Nucleic acid molecules encoding clot-specific streptokinase fusion proteins possessing altered plasminogen activation characteristics

ABSTRACT

The present invention provides polynucleotides encoding clot-specific streptokinase proteins possessing altered plasminogen characteristics, including enhanced fibrin selectivity. The kinetics of plasminogen activation by these proteins are distinct from those of natural streptokinase, in that there is a temporary delay or lag in the initial rate of catalytic conversion of plasminogen to plasmin. Also disclosed are processes for preparing the proteins.

This application is a divisional application of application Ser. No. 09/940,235, filed Aug. 27, 2001 which issued as U.S. Pat. No. 7,163,817, which is a continuation of application Ser. No. 09/471,349, filed Dec. 23, 1999, which is abandoned.

FIELD

The present invention relates to novel clot specific streptokinase proteins possessing altered plasminogen characteristics. The invention further relates to a process for the preparation of the said proteins. The streptokinases so produced have properties of chanced fibrin selectivity as well as kinetics of plasminogen activation that are distinct from that of natural streptokinase in being characterized by a temporary delay, or lag, of several minutes in the initial rate of the catalytic conversion of plasminogen to plasmin (a process termed hereafter as “PG activation”).

The advantage of this invention lies in the presence of these two properties in these chimeric (or hybrid) proteins together i.e. fibrin affinity and an initial lag in plasminogen activation. In other words, the hybrid protein molecules disclosed in this invention are both fibrin specific and display “delayed-action” thrombolysis. This confers on these novel proteins the ability to bind tightly with fibrin, the proteinaceous substance of blood clots soon after their introduction into the vascular system without significantly activating the circulating blood plasminogen to plasmin, thus aiding in the localization of the PG activation process to the site of the pathological thrombus. Thus, once the PG activation lag is overcome within a few minutes' of the exposure of the hybrid proteins to plasminogen, they can easily activate the plasminogen in the immediate vicinity of the thrombus in a manner essentially similar to that of natural i.e. unmodified streptokinase, thereby obviating the systemic PG activation frequently encountered during clinical use of streptokinase. These new hybrid proteins can therefore be used to advantage for thrombolytic therapy for various kinds of cardiovascular disorders.

BACKGROUND

In recent years, thrombolytic therapy with fibrinolytic agents, such as Streptokinase (SK), tissue plasminogen activator (TPA) or urokinase (UK) has revolutionized the clinical management of diverse circulatory diseases e.g., deep-vein thrombosis, pulmonary embolism and myocardial infarction. These agents exert their fibrinolytic effects through activation of plasminogen (PG) in the circulation by cleavage of the scissile peptide bond between residues 561 and 562 in PG. As a result, the inactive zymogen is transformed to its active form, the serine protease, plasmin (PN), which then acts on fibrin to degrade the latter into soluble degradation products. It may be mentioned here that PN, by itself, is incapable of activating PG to PN; this reaction is catalyzed by highly specific proteases like TPA, the SK-plasminogen complex, and UK, all of which possess an unusually narrow protein substrate preference, namely a propensity to cleave the scissile peptide bond in PG. However, unlike UK and TPA, SK has no proteolytic activity of its own, and it activates PG to PN indirectly by first forming a high-affinity equimolar complex with PG, known as the activator complex (reviewed in Castellino, F.J., 1981, Chem. Rev. 81: 431).

Of the several thrombolytic agents used clinically, SK is probably one of the most-often employed, particularly because of its markedly lower cost when compared to TPA and UK. However, the choice of thrombolytic agent during therapy is dictated by a number of factors besides cost, such as the presence of side-effects and their severity, in vivo metabolic survival of the drug (e.g., circulatory clearance rates), fibrin selectivity and/or affinity, immunological reactivity etc. SK is a highly potent PG activator, and has a relatively long plasma half-life—properties that, together, impart a certain advantage to this drug as compared to its counterparts viz, TPA and UK. However, due to a lack of any appreciable fibrin clot-specificity in the former, the administration of therapeutically effective doses of SK often results in systemic PG activation, resulting in hemorrhagic complications due to the proteolytic degradation of blood factors by the plasmin generated throughout the circulatory system. However, if a fibrin affinity and/or selectivity could be integrated integrated into SK, a molecule which otherwise possesses little fibrin affinity of its own, it would considerably enhance the therapeutic efficacy of this thrombolytic agent. With respect to the other coveted trait in a fibrinolytic agent, such as that described above for TPA above (viz., considerably lowered activity while circulating in the vascular system but enhanced PG activating ability in the presence of fibrin), attempts have been made in the past to produce analogs of SK with greater circulatory half-lives and decreased systemic plasmin generation by incorporating properties such as a slower rate of PG activation into the fibrinolytic agent. One example where this has been successfully accomplished is that of anisoylated streptokinase plasmin activator complex, abbreviated APSAC (sold under the trade-name ‘Eminase’ by the Beecham pharmaceutical group) (reference: Smith, R. A. G., Dupe, R. J., English, P. D., and Green, J.,1981, Nature 290:505) in which the catalytically important serine residue of the plasmin component is blocked by reversible aclyation. The generalized plasmin activation coincident with the administration of unmodified SK has been reported to be appreciably diminished during thrombolytic therapy with APSAC since the deacylation of the covalently modified serine in the SK-acylated plasmin complex occurs slowly in the vascular system.

It is thus generally recognised that it will be of significant clinical advantage if SK could be engineered to possess increased fibrin affinity/specificity together with a markedly slower initial rate of activation of PG. Thus, soon after injection into the body, whilst it is still in an inactive or partially active state, such a modified PG activator will bind to the pathological fibrin clot during its initial sojourn through the vascular system in an inactive/partially active state. However, after an initial lag (a property engineered into the derivative/analog through design) it will become fully activated after being sequestered to the fibrin clot by virtue of its fibrin affinity. Thus, the PG activation process will be relatively limited to the immediate vicinity of the clot, thus obviating the systemic PG activation coincident with natural SK administration which has no intrinsic fibrin affinity of its own and which activates PG as soon as it encounters it. In other words, whilst the former property in the novel protein/s would be expected to confer on the thrombolytic agent an ability to target itself to the immediate locale of the pathological clot and thus help build up therapeutically effective concentrations of the activator therein, the initially slow kinetics of PG activation would result in an overall diminished generation of free plasmin in the circulation. The net result shall be a continued and more efficient fibrinolysis at the target sustained by considerably lowered therapeutically effective dosages of the thrombolytic agent.

In the past, the gene encoding for SK has been isolated from its natural source (Streptococcus species) and cloned into several heterologous micro-organisms such as yeast (Hagenson, M. J., Holden, K. A., Parker, K. A., Wood, P. J., Cruze. J. A., Fuke. M., Hopkins, T. R., Stroman, D. W., 1989, Enzyme. Microb. Technol. 11:650), bacteria viz, E. coli (Malke, H, Ferretti, J. J., 1984, Proc. Nat'l. Acad. Sci. 81: 3557), alternate species of Streptococcus (Malke, H., Gerlach, D., Kohler, W., Ferretti, J.J., 1984, Mol.Gen.Genet. 196:360), and Bacillus (Wong, S. L., Ye, R., Nathoo S., 1994, Applied and Env. Microbiol. 1:517). In addition, genetically modified SK derivatives containing “Kringle” type fibrin binding domains derived from plasminogen, and methods of obtaining the same by rDNA techniques, have been described (EU 0397 366 A1). However, since five such Kringl regions are already present in the natural SK-PG activator complex, being an integral part of PG in the activator complex, the advantages gained from further addition of such domains are likely to be minimal. Hence, there is a need to impart a qualitatively different fibrin-affinity and/or specificity to the activator complex, particularly of a type associated with TPA, a very effective thrombolytic agent possessing much greater fibrin affinity than SK. TPA is known to contain a fibrin-associating “finger” domain, which is structurally and functionally very similar to the fibrin-binding domains present in fibronectin, a multi-functional protein with ability to interact with a number of other proteins besides fibrin e.g., collagen, heparin, actin etc (reviewed in Ruoslahti. E., 1988, Ann. Rev. Biochem. 57:375). Methods for the imaging of fibrin-containing substances, such as pathological clots and/or atherosclerotic plaques in vivo by using large radio-labeled polypeptides derived from fibronectin, and gearing these FBDs (fibrin binding domains) have been disclosed (see: PCT WO 91/17765); this patent also discloses chemically cross-linked FBD-containing polypeptides and a thrombolytic agent (SK) to effect thrombus-targeted fibrinolysis. The chemical cross-linking procedure resulted in the generation of a complex mixture of heterogenously cross-linked molecules with variable FBD and SK content, since the bifunctional agents used for chemical cross-linking essentially cross-link any of the large number of lysine side-chains present in the participating molecules viz. SK and HPG. Thus, this procedure generates mixtures of molecules with undefined location of the cross-links between the molecules e.g. both dimers and multimers with both hom—(e.g., SK-SK or FBD-FBD types) and hetero-crosslinked molecules with varying sites of cross-links are expected to be formed. In addition, it is noteworthy that the SK molecules chemically cross-linked with fibrin binding polypeptides disclosed in this patent showed an overall level of PG activator activity essentially comparable to that of unmodified SK, and no alteration was observed in the rate of PG activation, or the presence of an initial lag in the PG activation kinetics. It is quite clear that this invention related to the preparation of a heterogeneous population of cross-linked molecules with structures essentially undefined with respect to the cross-links' locations, and without any cross-correlation between the different structures in the ensemble of molecules and their corresponding functional properties. This is a serious limitation in the description of a drug intended for therapeutic application, in general, and with respect to the exact nature of the structure-function correlation in the collection of the cross-linked molecules, in particular.

In the past, hybrid SK derivatives with “kringle” type fibrin binding domains derived from human plasmin(ogen) fused to the former, and methods of obtaining the same by rDNA techniques, have been described (EU 0397 366 A1 and U.S. Pat. No. 5,187,098). However, five such Kringle regions are already present in the natural SK-Plasmin(ogen) activator complex, as noted before, being an integral part of PG in the activator complex, which has a weak fibrin affinity at best (Fears, R., 1989., Biochem. J. 261: 313). Hence, there is a need to impart a qualitatively different fibrin-affinity and/or specificity to the activator complex and utilize the affinity so imparted to obtain SK derivatives that display functional characteristics that help avoid the immediate activation of plasminogen upon contact with the latter.

Certain proteins are known to contain fibrin-associating “finger” domain/s, such as those present in fibronectin, a multi-functional protein with ability to interact with a number of other proteins besides fibrin e.g., collagen, heparin, actin etc (reviewed in Ruoslahti, E., 1988, Ann. Rev. Biochem. 57:375). TPA also possesses a “finger” type fibrin binding domain (FBD) that greatly helps in its fibrin association (Verheijen, J.H. et al., 1986., EMBO J. vol. 5, pp. 3525). Methods for the imaging of fibrin-containing substances, such as pathological clots and/or atherosclerotic plaques in vivo by using large radio-labeled polypeptides derived from fibronectin, and bearing these FBDs have been disclosed (see: PCT WO 91/17765); this patent also discloses chemically cross-linked FBD-containing polypeptides and a thrombolytic agent (SK) to effect thrombus-targeted fibrinolysis. However, it is noteworthy that the SK molecules chemically cross-linked with fibrin binding polypeptides showed an overall level of PG activator activity essentially comparable to that of unmodified SK, and no alteration was observed in the rate of PG activation or the presence of an initial lag in the PG activation kinetics. Besides, the cross-linking procedure resulted in the generation of a complex mixture of heterogenously cross-linked molecules with variable FBD and SK content, since the bifunctional agents essentially cross-linked any of the large number of lysine side-chains present in the participating molecules viz. SK and HPG likely generating both dimers and multimers with both homo- (e.g., SK-SK or FBD-FBD types) and hetero-crosslinked molecules. Moreover, this invention essentially disclosed the preparation of a heterogeneous population of chimeric molecules between SK and fibrin binding polypeptide with undefined covalent structures with respect to the sites of cross-linking as well as types of polymers so formed i.e. whether homo- (SK-SK or FBD-FBD types) or hetero-types, so that any meaningful structure-functional cross-correlation between the different structures in the ensemble and their corresponding functional properties cannot be obtained. This is a serious limitation in a drug intended for therapeutic application particularly one administered through a parenteral route in human beings.

In contrast the present invention provides novel clot-specific streptokinase proteins possessing altered plasminogen activation characteristics and a process for the preparation of different types of said proteins by recombinant DNA technology which have been designed using precisely defined elements of DNA polynucleotides that encode for fibrin binding domains and SK, or their modified forms. The hybrid proteins so formed thus have two very important structural as well as functional elements, namely SK or its modified forms, and ‘finger’ type fibrin binding domain/s attached to each other through covalent peptide bonds in a predefined and predetermined order of juxtaposition with respect to each other (see FIG. 1 for types of such constructs, and the rationale for their construction, which is provided below) so that the hybrid, or chimeric, proteins so produced after expression in a suitable system possess discrete, definable covalent structures. In other words, the novel hybrid proteins contain SK or functionally relevant parts thereof, connected through polypeptide linkage/s with the relevant protein domains of human fibronectin that are capable of independently conferring fibrin affinity to the resultant hybrids in such a manner that the hybrid protein/s specifically display altered plasminogen activation characteristics. The latter is marked by the presence of an initial period of lag of several minutes' duration in the rate of PG activation by the hybrid SK derivatives (viz., time-delayed PG activation), which is followed by high rates of PG activation akin to that displayed by unmodified SK. In other words, the duration of the initial lag, which varies depending on the type of hybrid construct, is rapidly followed by PC activation rates closely similar to that of natural type SK. The simultaneous presence of the afore-mentioned two distinct biochemical properties in the same clot-dissolver protein molecule renders these hybrid streptokinases as very useful drugs for targeted, time-delayed clot lysis during thrombolytic therapy.

The biologically active form of Streptokinase (SK) is either the SK-plasminogen or SK-plasmin molecule/s, formed in the circulatory system by the association of SK with endogenous plasminogen soon after its administration in vivo. This complex is also known as the activator complex, a highly specific protease that activates substrate molecules of plasminogen to plasmin, which proteolytically digests fibrin and helps restore blood circulation in occluded vessels (Castellino, C.J., 1981., Chem. Rev. 81.:431). Unlike free SK, which does not possess fibrin affinity, this complex already possesses substantial fibrin affinity of its own due to the “kringle” fibrin binding domains present in the plasmin(ogen) part of the SK-plasmin(ogen) activator complex Fears R., 1989., Biochem. J. 261:313: see also references cited therein). Nevertheless, unlike other preferred plasminogen activator protein drugs such as tissue plasminogen activator (TPA) which possesses intrinsic fibrin affinity as well as a fibrin-dependent plasminogen activation kinetics, the administration of SK during clot dissolution therapy often leads to unwanted systemic activation of plasminogen throughout the circulatory system due to immediate activation of circulating plasminogen, as opposed to the desired activation in and around the fibrin clot occluding the flow of blood through the affected vessel/s.

Thus, it will be of significant clinical advantage if SK could be engineered to possess increased fibrin affinity/specificity together with a markedly slower initial rate of activation of plasminogen (PG), but becoming capable of activating plasminogen in a manner similar to that of unmodified SK after an initial hiatus. Thus, soon after injection into the body, whilst it is still in an inactive or partially active state, the engineered SK will bind to the pathological fibrin clot while still in an inactive or partially active state, as it sojourns through the vascular system by virtue of the engineered fibrin affinity. However, after the initial lag in its PG activation kinetics is overcome in a few minutes, it will preferentially become activated in the immediate vicinity of the clot where it is now sequestered, thereby obviating or significantly minimizing the systemic PG activation coincident with natural SK administration which immediately activates PG upon administration. Thus, whilst the former property (of fibrin affinity) would be expected to confer on the new thrombolytic agent an ability to target itself to the immediate locale of the pathological clot and thus help build up therapeutically effective concentrations of the activator therein, the other property (of an initially slow kinetics of PG activation) would result in an overall diminished generation of free plasmin in the circulation. The net result shall be a continued and more efficient fibrinolysis at the target sustained by considerably lowered therapeutically effective dosages of the thrombolytic agent. In conclusion, a fibrin affinity per se in SK has little beneficial consequences (which anyway the SK-PG complex possesses in some measure) unless the systemic PG activation is thwarted and/or delayed.

An important attribute of the present invention is the preparation of different types of novel and hitherto undisclosed chimeric SK derivatives produced by recombinant DNA technology using defined gene-segments of SK and FBD combined in a pre-designed manner. These novel genetic constructs have been designed using precisely defined DNA elements that encode for SK and fibrin binding domains, or their modified forms so as to retain the functional characteristic of each (PG activation and fibrin affinity, respectively) as well as a characteristically altered PG activation kinetics. The chimeric proteins so produced have two types of elements (SK and the ‘finger’-type fibrin binding domains, or their modified forms) in a predefined and predetermined order of juxtaposition with respect to each other, so that the chimeric proteins expressed from these genes possess discrete, definable covalent structures. In other words, the chimeric proteins contain SK or parts thereof, connected through polypeptide linkage with the relevant protein domains that confer fibrin affinity to the resultant hybrids and also specifically result in altered kinetics of PG activation. The latter is characterized by an initial lag, or absence of PG activation, of several minutes' duration (viz., time-delayed PG activation), followed by high rates of PG activation akin to that of unmodified SK. The initial lag (which varies from approx. 8 min to 25 min depending on the design of the SK derivative) is rapidly followed by high rates of PG activation closely similar to that displayed by natural type SK. The simultaneous presence of the afore-mentioned two biochemical properties in the same PG activator molecule has not been disclosed in the SK-derived molecules in either of the patent disclosures cited above. In addition, the present patent discloses new combinations of DNA sequences that have been used to express the novel protein molecules with a unique combination of functional properties, mentioned above, which are not disclosed in the other patents.

The rationale for the construction of hybrid SK derivatives as disclosed in the process of the present invention with both fibrin specificity and delayed PG activation kinetics is explained below.

The molecular basis for the fibrin affinity displayed by fibronectin has been studied in some detail in recent years (Matsuka, Y.V., Medved, L.V., Brew. S.A. and Ingham; K.C., 1994, J. Biol. Chem. 269:9539). Under physiological conditions, FN first interacts reversibly (but with relatively high affinity) with fibrin and is then covalently incorporated into the fibrin clot matrix through clotting factor XIII, a transglutaminase (reviewed in Ruoslahti, E., 1988, Ann. Rev. Biochem. 57:375), whose action results in the covalent cross-linking between FN and a lys residue in fibrin(ogen) at the reactive Gln (residue 3) of the former. The region/s responsible for the interaction of FN with fibrin have been identified to resin both in the N-terminal as well as the C-terminal ends of this multi-domain protein. The N-terminal region of FN comprises of five finger modules (FBDs) as well as a transglutaminase cross-linking (TG) site, whereas the C-terminal region, lacking a TG site, contains three modules, as demonstrated by the binding of different polypeptides derived from FN carrying these two broad regions to fibrin-agarose. The exact domains in the N-terminal region responsible for the strong binding of the FN module, and their relative contributions towards this interaction have been analysed closely (Matsuka, Y.V., Medved, L.V., Brew, S.A. and Ingham, K. C., 1994, J. Biol. Chem. 269:9539 and Rostagno et al., 1994; J. Biol. Chem. 269: 31938) by expressing DNA segments encoding various combinations of the modules in heterologous cells and/or by examining the fibrin binding properties of polypeptide fragments carrying these modules prepared by limited proteolysis of FN. These studies clearly identified that of all the individual modules present in the N-terminal region of FN, the bi-modular arrangement viz., FBD 4 and 5 domains, displayed a fibrin affinity significantly comparable to the interaction of the full-length FN molecule, in contrast to all the other domains either as pairs or individually (including 4 and 5) which displayed poor affinity at 37° C. It is therefore clear from these studies that physiologically effective fibrin binding is not a common property of all the modules, either individually or in pairs, but is principally located in the FBD pair of 4 and 5, and to a relatively lesser extent, in domains 1 and 2.

To achieve the functional objective of an initially time-delayed PG activation kinetics by the hybrid SK derivatives, our design utilizes the fusion of selected regions of the FBDs of human fibronectin or its homologous sequences present in other proteins with SK (or its partially truncated forms) at strategically useful points so as to kinetically hinder the initial interaction of SK with PG necessary to form the 1:1 stoichiometric activator complex. It is known that of the 414 residues constituting native SK only the first 15 residues and the last 31 residues are expendable, with the resultant truncated polypeptide being nearly as active as the native full-length protein in terms of PG activation ability. Further truncation at either end results in drastic decrease in the activity associated with the molecule (Malke, H., Roe, B., and Ferretti, J. J. (1987) In: Streptococcal Genetics. Ferretti, J. J., and Curtis, R. III [Ed.] Proc. American Society for Microbiology., Wash. D.C. p. 143). It has been demonstrated that SK interacts with PG through at least two major loci, mapped between residues 16-51 and 230-290 (Nihalani, D., Raghava, G. P. S., and Sahni, G., 1997, Prot. Sci. 6:1284), and probably also the region in and around residues 331-332 (Lin, F. L., Oeun S., Houng, A., and Reed, G. L., 1996, Biochemistry 35:16879); in addition, the sequences at the C-terminal ends, especially before the last 30-32 residues of the native sequence (Kim. I. C., Kim, J. S., Lee, S. H., and Byun, S. M. 1996, Biochem. Mol. Bio. Int. 40:939. Lee, S. H., Jeong, S. T., Kim, I. C. and Byun S. M. 1997 Biochem. Mol. Bio. Int. 41:199. Fay, W. P., Bokka, L. V., 1998, Thromb. Haemost. 79;985) are important in generating the activator activity associated with the complex. Since a primary consideration in designing the SK-FBD chimeras was the engineering of a decreased, or kinetically slowed, initial PG activation rate, we reasoned that either the C- or N-termini (or both, together) could be utilized to bear the FBDs in the hybrid structures, and that the presence of such extra domains in SK, either full-length or already truncated to the most functionally relevant regions of human fibronectin that can independently bind fibrin under physiological conditions (detailed earlier) and would also suitably retard and/or delay the PG activation rates observed normally with native SK and PG by interfering in the interactions of SK with PG to generate a functional activator complex. If the polypeptide in between these two distinct parts constituting the chimera were sufficiently flexible, proteolytic scission in this region would then result in the removal of the retarding/inhibiting portion (FBD component) from the SK-FBD hybrid and lead to a burst of PG activation after an initial delay. This proteolysis could be mediated by the small amounts of endogenous plasmin generated in the vicinity of the pathological clot by intrinsic plasminogen activator/s of the system, such as TPA, urokinase etc already present in the circulatory system. Indeed, this premise was borne out by experimentation, which showed that the lag times of PG activation by the SK-FBD chimeras disclosed in this invention were directly governed by plasmin-mediated proteolysis of the hybrid proteins leading to the liberation of the FBD portion from the SK-FBD followed by rapid PG activation by the SK. The direct implication of this functional property in a plasminogen activator is that once injected into the body, the protein could then traverse in an inactive state through the circulatory system and bind to the pathological clot by virtue of the fibrin affinity imparted by the fibrin binding domains thereby obviating or minimizing systemic PG activation. Thus, if the thrombolytic agent traverses the circulation prior to this activation (which is known to require 3-5 minutes in the human circulation), the fibrin affinity in the chimera would allow it to bind to the clot, thereby helping to localize the PG activation in and around the immediate vicinity of the thrombus.

The amino acid sequence of human FN is known to be composed of three types of homologous repeats (termed type-1, type-2 and type-3), of which the FBDs at the amino terminus of FN are made of five type-1 repeats, each approximately 50 residues long and containing two disulfide bridges. The C-terminus of FN also has three type-2 homology repeats that are involved in fibrin-FN interactions. Therefore, altogether, a large portion of the FN molecule, representing the several N- and C-terminally located FBDs, could be linked with SK if all of the fibrin interacting regions need to be incorporated into the contemplated SK-FBD chimeras. However, such a design produces a chimeric protein that is not only too bulky, but also decreases the probability for the polypeptide to fold into a biologically active conformation due to the presence of a large number of S-S bridges that may form non-native, intra- and inter-molecular disulfide bonds. Instead, a potentially more worthwhile proposition is to seek miniaturised but, nevertheless, functionally active combinations of selectively truncated regions of SK and/or FBDs.

OBJECTS

The main objective of the invention is to provide a novel chimeric streptokinase-based plasminogen activator protein molecule with advantageous characteristics of improved fibrin affinity and plasminogen activation kinetics characterized by an initial lag of several minutes' duration (5 to 30 minutes) prior to attainment of full-blown capability of PG activation.

Another object is to provide a system for the production of the hybrid polypeptides, which includes DNA segments/polynucleotide blocks encoding the polypeptides, plasmids containing these genetic elements capable of their expression into protein, as well as microorganisms transformed with these plasmids.

Yet another object is to design a process for the production of the hybrid plasminogen activator protein molecules in pure and biologically active form for clinical and research applications.

Another object is to provide an improved process for the intracellular production of large quantities of SK, or its modified forms, in E. coli using an altered DNA polynucleotide, and obtain these in a pure and biologically active form.

A further object is to provide pharmaceutical compositions comprising novel chimeric streptokinase-based plasminogen activators of the invention and pharmaceutically acceptable carriers.

SUMMARY

The invention provides hybrid plasminogen activator comprising a polypeptide bond union between streptokinase (SK), or modified forms of SK, or suitable parts thereof, which are capable of plasminogen (PG) activation, with fibrin binding regions of human fibronectin selected from the pair of fibrin binding domains 4 and 5, or domains 1 and 2, or modified forms thereof, to achieve various motifs for joining the fibrin binding domains with streptokinase or its modified forms, so that the hybrid plasminogen activator possesses the ability to bind with fibrin independently and also characteristically retains a plasminogen activation ability which becomes evident only after a pronounced duration, or lag, after exposure of the plasminogen activator to a suitable animal or human plasminogen.

DETAILED DESCRIPTION

The present invention provides a hybrid streptokinase-based plasminogen activator prepared by conventional recombinant DNA techniques e.g., those described in ‘Sambrook et al., Molecular Cloning: A Laboratory Manual’ (II^(nd) Ed., Cold Spring Harbor Press, 1989) and ‘DNA Cloning’ (vol. I to III) (Glover, D.M., [Ed.], IRL Press Ltd., London, 1987), among several other manuals/compendia of protocols, and the techniques of protein purification and characterization, in particular the various chromatographic methods employed conventionally for purification and downstream processing of natural and recombinant proteins and enzymes viz., hydrophobic interaction chromatography (HIC), ion-exchange and gel filtration chromatographies, and affinity chromatographic techniques well-known in the field of protein biochemistry (e.g., in this regard, reference may be made to: (i) Protein purification. Principles, high resolution methods and applications. Janson, J-C., and Ryden, L., [Ed.], VCH Publishers Inc., New York, 1989; (ii) Process Chromatography: A practical guide. Sofer, G.K., and Nystrom, L.E., [Ed.], Academic Press, New York, 1989).

The advantage of the present invention lies in its disclosure of the design of structurally defined hybrid DNA polynucleotide constructs in which the translational in-frame fusion of the DNAs encoding SK or its modified forms, and the minimally essential parts of the fibronectin-encoding DNA polynucleotides essential for significant fibrin affinity on their own, such as those FBDs that possess independent fibrin binding capability (such as finger domains 4 and 5 of human fibronectin) is carried out in such a configuration that confers the additional property of a time-delayed plasminogen activation in the resultant hybrid protein molecules. The latter are expressed by translation of the hybrid polynucleotides formed between the SK-encoding DNA and the FBD encoding DNA in a suitable host cell such as a bacterium, yeast, animal, plant cell etc. The resultant hybrid proteins, containing SK and FBD portions fused to each other through polypeptide linkages, can be isolated in pure form by conventional methods of protein purification.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1. Schematic representation of different chimeric proteins prepared by the fusion f SK and FBDs.

FIG. 2. Map of plasmid pJKD-8, containing SK gene from S. equisimilis H46A.

FIG. 3-1 to 3-2 shows the DNA and protein sequence of streptokinase of S. equisimilis H46A (SEQ ID NOs:1 and 2, respectively) (GenBank accession number: gb/K02986/STRSKC).

FIG. 4. Partial restriction enzyme map of DNA encoding for SK.

FIG. 5. Map of plasmid pFH-6, containing FBD 1 to 5 encoding sequences according to Kornhblitt, A.R., Umerzawa, K., Vibe-Pedersen, K. and Baralle, F.E., (1985) EMBO J. 4:1755.

FIG. 6. DNA and protein sequence of the gene-segment encoding for FBDs 1-5 of human fibronectin (SEQ ID NOs:3 and 4, respectively) (the DNA sequence has been obtained from EMBL; file and accession no X02761.

FIG. 7. Restriction enzyme map of DNA encoding the five N-terminally located FBDs of human fibronectin.

FIG. 8 Map of plasmid pET23(d).

FIG. 9. Flow chart schematically depicting the main steps in the construction of a plasmid vector for the expression of the native SK gene of S. equisimilis H46A.

FIG. 10. Flow diagram schematically depicting the main steps involved in the repair of the vector pET23(d)SK i.e construction of expression vector pET23(d)SK-NTRN (NTRN: abbrev. form for N-terminally repaired with native sequence).

FIG. 11. Nucleotide sequence of SK-NTRN gene (SEQ ID NO:5).

FIG. 12. Predicted secondary structure of native (A) and translationally silently modified (B) 5′-ends of the SK gene sequence (SEQ ID NOs:27 and 28, respectively).

FIG. 13. Schematic flow diagram depicting the main steps in the construction of a plasmid vector [pET23(d)SK-NTR] for the intracellular hyper-expression of a semi-synthetic SK gene in which the 5′-end of the open-reading-frame for SK was selectively modified in translationally silent manner at the DNA level, so that it encoded for the primary structure of S. equisimilis SK.

FIG. 14. Nucleotide sequence of SK-NTR gene (SEQ ID NO:6).

FIG. 15. Schematic depiction of the intergenic region of the chimeric SK-FBD(4,5) gene (above: SEQ ID NO:8; below: SEQ ID NO:7) highlighting the design of a gly-gly-gly sequence, a transglutaminase cross-linking site and several unique restriction enzyme sites wherein different inter-genic cassettes can be conveniently swapped into this region. Also shown is the location of the natural Bsm I site in the SK gene which was exploited as the common junction point for joining the FBD sequences to the SK gene.

FIG. 16. Flow diagram depicting the main steps in the construction of plasmid pSKMG400, containing the SK-FBD(4,5) hybrid DNA block composed of FBD(4,5) sequences linked to the intergenic sequences at its 5′-end, and the SK gene fused in-frame at the 3′ end.

FIG. 17 a. Scheme depicting the cloning of the hybrid SK-FBD(4,5) cassette into pET23(d)SK-NTR for intracellular expression of SK-FBD(4,5) chimeric protein in E. coli.

FIG. 17 b. DNA sequencing data of SK-FBD(4,5) hybrid cassette in T7 expression vector, pET23(d) (SEQ ID NO:9).

FIG. 18. Schematic flow diagram for cloning of SK-FBD(1,2) hybrid gene in pBluescript to obtain pSKMG400-FBD(1,2).

FIG. 19 a. Schematic description of steps involved in the cloning of the hybrid gene-construct SK-FBD(1,2) into expression vector pET23(d)SK-NTR for intracellular expression of SK-FBD(1,2) chimera in E. coli.

FIG. 19 b. DNA sequencing data of SK-FBD(1,2) hybrid cassette in T7 expression vector (SEQ ID NO:10).

FIG. 20. Scheme of steps involved in the construction of hybrid gene block composed of DNA encoding for FBD(4,5) and residues 1-63 of SK by the Overlap Extension PCR technique.

FIG. 21 a. Scheme depicting steps involved in the cloning of the FBD(4,5)-SK gene block for expression of FBD(4,5)-SK chimera in E. coli.

FIG. 21 b. DNA sequencing data of FBD(4,5)-SK gene block as present in the T7 expression vector pET23(d)-FBD(4,5)-SK (SEQ ID NO:11).

FIG. 22 a. Flow chart depicting schematically the steps involved in the construction of FBD(4,5)-SK-FBD(4,5) hybrid gene in pET23(d) expression vector.

FIG. 22 b. DNA sequencing data of FBD(4,5)-SK-FBD(4,5) gene block as present in the T7 expression vector pET23(d)FBD(4,5)-SK-FBD(4,5) (SEQ ID NO:12).

FIG. 23. Purification of SK-FBD(4,5) protein expressed in E. coli by a one-step affinity chromatographic procedure.

FIG. 24. Clot lysis by purified SK-FBD(4,5) chimeric protein in a plasma milieau. FIG. 24 shows results with: closed triangles, 100 nm SK; open triangles, 50 nm SK; closed circles, 200 nm SK-FBD(4,5); closed squares, 100 nm SK-FBD(4.5); open squares, 50 nm SK-FBD(4,5).

Accordingly, the present invention provides a hybrid plasminogen activator comprising a polypeptide bond union between streptokinase (SK), or modified forms of SK, or suitable parts thereof, which are capable of plasminogen (PG) activation, with fibrin binding regions of human fibronectin selected from the pair of fibrin binding domains 4 and 5, or domains 1 and 2, or modified forms thereof, so that the hybrid plasminogen activator possesses the ability to bind with fibrin independently and also characteristically retains plasminogen activation ability which becomes evident only after a pronounced duration, or lag, after exposure of the plasminogen activator to a stable animal or human plasminogen. FIG. 1 describes the different designs of the SK-FBD hybrid proteins schematically as disclosed in the invention.

In an embodiment, the invention provides a hybrid plasminogen activator which carries out plasminogen activation only after a lag period varying between 5 and 30 minutes after exposure of the plasminogen activator to a suitable animal or human plasminogen.

In a further embodiment, the invention provides a DNA segment encoding the hybrid plasminogen activator.

In yet another embodiment, the invention provides an expression vector containing a DNA segment encoding the hybrid plasminogen activator.

In another embodiment, the invention provides prokaryotic or eukaryotic cells, transformed or transfected with expression vectors, and capable of expressing the hybrid plasminogen activators.

The invention further provides a method for the preparation of hybrid plasminogen activators possessing useful plasminogen activation characteristics, said method comprising the steps of:

-   -   (a) Preparing a first DNA encoding a nucleotide sequence for         streptokinase or any of its modified forms, by conventional         biochemical or chemical methods or appropriate combinations         thereof, to produce a translational product which is a         polypeptide that can activate plasminogen.     -   (b) Preparing a second DNA polynucleotide by known biochemical         or chemical methods or appropriate combinations thereof, that         encodes for the fibrin binding domains selected from the pair of         fibrin binding domains 4 and 5, or domains 1 and 2, or their         modified forms, that are capable of conferring affinity and/or         specificity for fibrin, and linking these to another DNA         molecule that is capable of undergoing multiplication in a         suitable host cell,     -   (c) Construction of hybrid polynucleotides, between the first         DNA encoding for streptokinase, or its modified forms, that         encode for a polypeptide capable of plasminogen activation, with         the second DNA encoding for the fibrin binding domains (FBD) of         fibronectin by conventional methods, in the native translational         codon frame starting with an initiator codon, and joining of the         hybrid polynucleotide into a recipient DNA molecule, such as a         plasmid capable of autonomous replication in a host cell, or         capable of integrating into the genomic DNA of a suitable host         cell, and expressing the hybrid protein therein,     -   (d) Introducing the DNA containing the hybrid polynucleotide         constructs obtained in step (c) into an appropriate host,         selected from the group comprising E. coli, Bacillus sp., yeast,         fungus, plant, animal cell by conventional methods,     -   (e) Culturing the host cells expressing the SK-FBD chimeric         polynucleotide using known procedures,     -   (f) Isolating components of the culture, selected from         extracellular fluid from fermentation, intracellular milieau of         the host cell or combinations thereof, that harbour the         expressed chimeric polypeptide in an enriched form and then         partially purifying the chimeric polypeptides using conventional         procedures selected from the group comprising centrifugation,         ultrafiltration, precipitation with salts or organic solvents         etc, or chromatography on suitable media, or combinations         thereof;     -   (g) Refolding the hybrid polypeptide to a biologically active         and structurally intact form, if required,     -   (h) Further purifying the biologically active hybrid polypeptide         from the relatively crude or partially pure material/s or         cell-free lysate obtained at step (f), or     -   (g) above, after refolding, using conventional methods of         protein purification, or by affinity chromatography on a         suitable matrix comprising immobilized fibrin or fibrinogen, or         specific antibodies that recognize and bind with the active,         biologically active hybrid proteins,

In an embodiment, the invention provides a method for the production of the hybrid plasminogen activator proteins including DNA segments/polynucleotide blocks encoding the polypeptides, plasmids containing these genetic elements capable of their expression into protein, as well as microorganisms or other suitable host cells transformed with these plasmids.

In another embodiment, the invention provides a method for the production of the hybrid plasminogen activator molecules in pure and biologically active form for clinical and research applications.

In another embodiment, the invention provides a method for the intracellular production of large quantities of SK, or its modified forms in bacteria such as E. coli, using a polynucleotide block that is altered as compared to that of the natural DNA sequence encoding for SK or its modified forms, and obtain these in a pure and biologically active form.

In yet another embodiment, the invention provides a method wherein the 5′-end of the SK-encoding polynucleotide utilized for expression of SK, or its modified forms such as the SK-FBD chimeric polypeptides, is modified, as exemplified by the DNA sequence provided in FIG. 13, by mutagenesis by known biochemical or chemical DNA synthesis techniques, or their combination, such that the secondary structure-forming capability (e.g., the intramolecular hydrogen bonding capability) of its transcript is diminished, resulting in increased efficiencies of expression of SK or its modified forms such as SK-FBD chimeras in the heterologous host cell.

In another embodiment, the invention provides a method wherein the 5′-end of the SK-encoding DNA or its modified forms such as the SK-FBD chimeric polypeptides is modified by mutagenesis by known biochemical or chemical DNA synthesis techniques, or a suitable combination thereof, in such manner that the codons utilized in the DNA polynucleotide art compatible with those frequently utilized in E. coli or the host cell used for the expression of the genes.

In another embodiment, the invention provides a method wherein the DNA encoding those fibrin binding domains that possess independent fibrin binding capability are fused in the correct translational frame at the 5′-end of the SK-encoding DNA, after a translational start codon, and then expressed into protein of the form exemplified in FIG. 1C, refolded oxidatively and isolated in the purified form, to obtain the desired characteristic in the chimera viz., characteristic PG activation properties characterized by an initial lag in the PG activation rates together with significant fibrin affinity.

In another embodiment, the invention provides a method wherein the fibrin binding domains are fused in-frame at the C-terminal end of the SK, or its modified form, to obtain a hybrid SK-fibrin binding domain protein that contains selected fibrin binding domains at the C-terminal end of the SK portion of the chimera after expression of the hybrid DNA in a suitable host cell, as exemplified in FIGS. 1A and 1B, to obtain the desired characteristic in the chimera viz., characteristic PG activation properties characterized by an initial lag in the PG activation rates together with significant fibrin affinity.

In another embodiment, the invention provides a method wherein the fibrin binding domains are fused through polypeptide linkage at the C-terminal end of the SK devoid of upto 45 amino acids, preferably 31 amino acid residues. Thus, a hybrid SK-FBD protein is generated that contains selected fibrin binding domains fused at the C-terminal end of a truncated SK, thus yielding a chimeric protein that has both fibrin affinity as well as delayed PG activation properties.

In yet another embodiment, the invention provides a method wherein fibrin binding domains are fused at both the ends of SK, or its modified forms that retain a plasminogen activator ability, simultaneously (in the configuration represented as FBD-SK-FBD; as schematically depicted in FIG. 1, D) to achieve the desired functionality in the hybrid construct viz, characteristic plasminogen activation properties characterized by an initial lag in the PG activation rates together with significant fibrin affinity.

In another embodiment, the invention provides a method wherein the novel, chimeric polypeptides are expressed in E. coli or other suitable host cells.

In another embodiment, the invention provides a method wherein SK or its truncated form/s are fused through polypeptide linkages with the fibrin binding domains known to possess independent fibrin binding capability through a short linker peptide region comprising of a stretch of amino acid sequence that is not conformationally rigid but is flexible, such as those predominantly composed of Gly, Ser, Asn, Gln and similar amino acids.

In another embodiment, the invention provides a method wherein SK or its modified forms are fused with fibrin binding domains through a “linker” peptide composed of amino acid sequences that provide varying levels of local conformational flexibility by incorporating sequences that fold into relatively rigid secondary structures such as beta-turns so as to obtain different chimeric PG activator proteins with desirable initial lag-times in their plasminogen activation kinetics.

In another preferred embodiment, the SK-FBD hybrid polypeptides are expressed in E. coli using known plasmids under the control of strong promoters, such as iac, trc, trp, T7 RNA polymerase and the like, which also contain other well known features necessary to effect high level expression of the incorporated DNA polynucleotides encoding for the hybrid Streptokinase-fibrin binding domain polypeptides e.g. Shine-Delgarno sequence, transcription terminating signals etc.

In yet another embodiment, SK or its truncated forms are fused either at the amino or C-termini, or both, through polypeptide linkages with the FBDs known to possess independent fibrin binding capability, such as domains 4 and 5, through short ‘linker ’ regions, as described above, that contain amino acid sequence/s providing varying levels of local conformational flexibility to the linker segment between the SK and FBD portions of the hybrid protein/s.

In yet another embodiment, various chemical or physical agents, such as iso-propyl-beta-D-thio galacto pyranoside (IPTG), lactose, low or high temperature change, change in salt or pH of medium, ethanol, methanol, and the like, are used to induce high levels of the SK or the various hybrid polypeptides in the host cell in which the hybrid polynucleotides are being expressed.

In another preferred embodiment, the hybrid SK-FBD polynucleotides are expressed in E. coli.

In yet another embodiment, the E. coli cells are lysed by chemical treatment such as the use of chaotropic salts e.g. guanidinium hydrochloride and the like, to effect the liberation of the SK or its modified hybrid forms, which are then purified using conventional procedures.

In yet another embodiment, the invention provides a method wherein the host E. coli cells are lysed by chemical treatment such as chaotropic salts e.g., guanidinium hydrochloride and the like, to effect the liberation of the SK or its modified chimeric forms, followed by purification using conventional methods.

In another embodiment, the invention provides a method wherein the crude cell-lysates obtained, using either conventional methods or by employing chaotropic salts, from cells elaborating the chimeric polypeptides are subjected to air oxidation to refold chimeric polypeptides to their biologically active conformations containing the native cystine connectivities.

In another embodiment, the invention provides a method wherein the crude cell-lysates obtained using either conventional methods selected from the group consisting of enzymatic lysis of cells, ultrasonic lysis, lysis by mechanical means or by employing chaotropic salts, from cells elaborating the chimeric polypeptides are subjected to oxidation and refolding using a mixture of reduced and oxidized glutathione of a suitable redox potential that allows the chimeric polypeptides to refold to their biologically active conformations.

In yet another embodiment, the invention provides a method wherein the refolding reaction is carried out in the presence of immobilized fibrin to promote a more efficient ligand-induced refolding of the epitopes responsible for fibrin affinity in the said chimeric polypeptides, and consequently higher yields of the biologically active chimeric protein constructs.

In another embodiment, the invention provides a method wherein the biologically active chimeric polypeptides are purified selectively from other proteins, or unfolded SK-FBD polypeptides, by affinity chromatography on immobilized fibrin(ogen) e.g. fibrin- or fibrinogen-agarose.

In another embodiment, the invention provides a method wherein a chimeric plasminogen activator protein is used as a medicant for the treatment or propylaxis of thrombolytic diseases. The activator may be formulated in accordance with routine procedures as pharmaceutical composition adapted for intravenous administration to human beings, and may contain stabilizers such as human serum albumin, mannitol ect, solubilizing agents, or anesthetic agents such as lignocaine and the like.

In yet another embodiment, the invention provides a pharmaceutical composition comprising a hybrid plasminogen activator and stabilizers such as human serum albumin, mannitol etc, solubizing agents, anesthetic agents.

In a further embodiment, the pharmaceutical composition of the invention comprises a chimeric plasminogen activator protein used as a medicant for the treatment or prophylaxis of thrombolytic diseases and pharmaceutically acceptable carriers. The activator may be formulated in accordance with routine procedures as pharmaceutical composition adapted for intravenous administration to human beings, and may contain stabilizers such as human serum albumin, mannitol etc, solublizing agents, or anesthetic agents such as lignocaine and the like.

The DNA polynucleotides encoding the various streptokinase-fibrin binding domain hybrid constructs depicted schematically in FIG. 1 can be made utilising rDNA and selective DNA amplification techniques (e.g., the well-known polymerase chain reaction technique, abbreviated PCR) (reference, in this regard may be made to Saiki, R. K., Scharf, S., Faloona, F., Mullis, K.B., Horn, G.T., Erlich, H.A., and Amheim, N., 1985, Science 230: 1350; Mullis, K.B., and Faloona, F., 1987, Methods in Enzymol. 155.335). The hybrid genes are then expressed in heterologous hosts such as bacteria (e.g. E. coli), or other suitable organisms, to obtain the chimeric polypeptides. Bacterial host cells (E. coli XL Blue) harbouring the various plasmid constructs expressing the different SK-FBD hybrid proteins (see Examples section) have been deposited in the Microbial Type Culture Collection (MTCC), Institute of Microbial Technology, Chandigarh (a constituent laboratory of C.S.I.R., India). The accession numbers of these constructs are: BPL 0013 for the pET 23(d)-NTR-SK-FBD(4,5) construct (see FIG. 17 a for map of this plasmid); BPL 0014 for pET 23(d)-SK-NTR-FBD(1,2) (see FIG. 19 a); BPL 0015 for pET23(d)FBD(4,5)-SK (see FIG. 21 a for map of this plasmid construct); BPL 0016 for pER23(d)FBD(4,5)-SK-FBD(4,5) (See FIG. 22 a for map); 0017 for pET23(d)SK-NTR (see FIG. 13 for map of this plasmid construct). The proteins expressed from these plasmids can be expressed in suitable host cells (e.g. E. coli BL 21) and then purified to render them substantially free of other components derived from the host producer cells. In case the polypeptide is expressed in a host system not capable of efficient re-oxidative folding of the primary translational product/s of the hybrid genes e.g. E. coli, an intermediate in vitro refolding step is introduced subsequent to the expression step. Alternatively, the hybrid constructs can be expressed in cell systems capable of efficient oxidative refolding of translational products e.g. yeast, animal cells etc.

The DNA polynucleotide encoding for SK was first cloned in a bacterial plasmid in E. coli after isolation from the wild-type S. equisimilis genomic DNA according to known procedures (Malke, H., and Ferretti, J.J., 1984; Proc. Nat'l Acad. Sci. 81: 3557) and in recent research publications available in the public domain (Pratap, J., Kaur, J., Rajamohan, G., Singh, D., and Dikshit, K.L., 1996, Biochem. Biophys. Res. Commun. 227:303). In the process of the present invention, the DNA corresponding to the translational open-reading-frame (ORF) of SK has been further modified with respect to its 5′-coding sequences so that after cloning in an expression vector under the control of a strong promoter, large quantities of biologically active SK are produced intracellularly. The DNA sequence of the SK gene from Streptococcus species (American Type Culture Collection accession No. 12449; this strain has served as the producer strain for numerous studies on streptokinase, and is often referred to as Streptococcuc equisimilis H46A in the scientific literature). The corresponding amino acid sequence of the mature protein are provided in FIG. 3. The restriction enzyme map of the SK-encoding DNA is provided in FIG. 4.

The DNA polynucleotide sequences encoding for the fibrin binding domains of human fibronectin were selectively amplified from known plasmids containing cloned cDNA for the FN gene. Kornhblitt, A.R., Vibe-Pedersen, K., and Baralle, F.E., 1983. Proc. Nat'l Acad. Sci. 80:3218 have cloned the cDNA encoding for the human fibronectin (FN) gene in a plasmid vector in E. coli (pFH1). This cDNA extends approx. 2.1 kb from the poly-A tail of the mRNA of fibronectin, around one-fourth of the estimated size of the human FN message (approx. 7900 nucleotides). By further mRNA “walking” type of experiments, these investigators carried out the contruction of longer cDNA clones using synthetic oligonucleotides complementary the DNA of clone pFH1. By this method, cDNAs corresponding to the complete FN mRNA were prepared and cloned in several vectors (Kornhblitt A.R., Umezawa, K, Vibe-Pedersen, K., and Baralle, F.E., (1985) EMBO J. 4:1755). One such plasmid (pFH6) contained the entire sequences coding for the FBDs of the N-terminal region of human FN (as represented in FIG. 5 showing the map of this plasmid, and in FIG. 6 showing the nucleotide and amino acid sequence of the FBD regions contained in this plasmid and FIG. 7 for its restriction enzyme map). Plasmid pFH6 served as the source for these sequences in the construction of the SK-FBD hybrids. The fibrin binding domains located in the N-terminal region of human FN gene were selectively amplified by PCR using specially designed oligonucleotide primers that hybridized with DNA sequences flanking the FBD DNA segments to be amplified. These primers also contained non-hybridizing sequences at their 5′-ends that provided the intergenic sequence (i.e. between the SK and FBD DNA) as well as a restriction site through which the amplified DNA could be ligated with the SK gene in-frame in a plasmid vector. The cloned hybrid gene was then expressed in E. coli so as to produce large quantities of the chimeric polypeptide. This protein was then isolated from the E. coli cells and subjected to a process of purification and refolding to a biologically active form. Similarly, different designs of the SK and FBD hybrids were then constructed using recombinant DNA methods, expressed, and isolated in biologically active, purified forms. Analysis of the properties of these proteins established that these indeed possessed the functional properties expected from their design i.e. plasminogen activation ability as well as fibrin selectivity. They also displayed the additional desired property of a very slow initial kinetics of PG activation, which, after a lag varying between 5-30 minutes, depending on the construct, was overcome, leading to high rates of PG activation comparable to native SK.

The invention and its embodiments are illustrated by the following examples, which should not be deemed to limit the scope of the invention in any manner. Various modifications that may be apparent to those skilled in the art are deemed to fall within the scope of the invention

I. General Methods Used in Examples.

1. Recombinant DNA methods: In general, the methods and techniques of rDNA well known in the area of molecular biology were utilised. These are readily available from several standard texts and protocol manuals pertaining to this field of the art, for example, Sambrook et al., Molecular Cloning: A Laboratory Manual (II^(nd) edition, Cold Spring Harbor Press, New York., 1989; McPherson, M.J., Quirke, P., and Taylor, G.R., [Ed,] PCR: A Practical Approach. IRL Press, Oxford., 1991). However, pertinent details in the context of specific experiments describing the present invention, particularly where modifications were introduced to established procedures, are indicated in the Examples wherever relevant. 2. Casein-plasminogen overlay for detection of SK activity: bacterial colonies producing streptokinase can be routinely detected by overlay of casein and human plasminogen in soft agar (Malke, H., Ferretti, J.J., 1984, Proc. Natl. Aca. Sci. 81:3557). Ten ml soft agarose mixture consisting of 0.8% agarose, 10% skimmed milk, approx. 200 ug of human plasminogen, 150 mM NaCl, and 50 mM Tris-Cl (pH 8.0) is poured on top of the plates. The plates are incubated at 37° C. for 2-6 h. Positive streptokinase activity is indicated by the appearance of zones of clearance around the colonies (halo formation). 3. Zymography: proteins from total cell lysates are separated on 10% SDS-PAGE. After completion of electrophoresis run, gel is washed with 2.5% Triton X-100 to remove any SDS. It is then thoroughly rinsed with standard buffer 0.05 M Tris Cl (pH 7.5) for Triton X-100 removal. The gel is laid on 0.6% agarose plate containing 10% skimmed milk and 0.5 mg/ml human plasminogen. After incubating at 37° C. for 2-3 h, an active SK band is visualized as a clear band. 4. SDS-PAGE analysis of proteins: SDS-PAGE is carried out, essentially according to Laemmli, U.K., 1970, Nature 227:680 with minor modifications, as needed. Briefly, protein samples are prepared by mixing with an equal volume of the 2× sample buffer (0.1 M Tris Cl, pH 6.8; 6% SDS; 30% glycerol; 15% bcta-merecaptoethanol and 0.01% Bromophenol Blue dye). Prior to loading onto the gel, the samples are heated in a boiling water bath for 5 min. The discontinuous gel system usually has 5% (acrylamide conc.) in the stacking and 10% in the resolving gel. Electrophoresis is carried out using Laemmli buffer at a constant current of 15 mA first, till the samples enter the gel and then 30 mA till the completion. On completion of electrophoresis, gel is immersed in 0.1% coomasie Blue R250 in methanol: acetic acid: water (4:1:5) with gentle shaking and is then destained in destaining solution (20% methanol and 10% glacial acetic acid) till the background becomes clear. 5. Immuno-assay of Western bloted-proteins: Wester blotting of the proteins from E. coli carrying plasmid encloded intracellular streptokinase is carried as detailed (Towbin, H., Stachelin, T., Gordon, T., 1979, Proc. Natl. Acad. Sci. 76: 4350). The cultures are grown to 600 nm of 0.5-0.6, and are induced with 1-5 mM IPTG. The cells are centrifuged. The pellet is resuspended in cell lysis buffer and the supernatant obtained after high-speed centrifugation. These fractions are resolved on the 10% SDS-PAGE. The gel is equilibrated with the transfer call buffer (25 mM Tris, 175 mM glycine in 20% methanol) and is blotted electrophoretically in to the nitrocellulose membrane at 50 V for 3 h. The blot is blocked with 5% skimmed milk (Difco) in PBS (Phosphate buffer saline) for 14-16 h at 4° C. The blot is further washed with 0.1% Tween-20 in PBS. The blot is incubated with the anti-SK antibodies (raised against pure S. equisimilis SK in rabbit) in 40 ml of PBS containing 5% skimmed milk for 3 h at room temperature with gentle shaking. The blot is washed with 0.1% Tween 20 in PBS three times for 15 minutes each. Again it is blocked with PBS-skimmed milk for 15 min with gentle shaking at room temperature and further incubated with peroxidase-conjugated goat anti-rabbit immunoglobulins at a dilution of 1:5000 in 20 ml of PBS-skimmed milk (5%) for two 2 h at room temperature with gentle shaking. the filter is again washed with 0.1% Tween 20 in PBS for three times (15 min each). The colour reaction for HRP-linked secondary antibodies is carried out by immersing the blot in 10 ml of reaction buffer solution having 10 mg of DAB (di-amino benzidine) and imidazole each. The reaction is terminated by washing with distilled water. 6. Streptokinase assay using chromogenic peptide substrate: plasminogen activator activity of streptokinase is assayed according to Jackson, K.W., Esmon, N., Tang, T., 1981, Methods in Enzymology 80: 387. One hundred ul of appropriately diluted streptokinase samples, 25 ul of sample buffer (0.15 M Tris-Cl buffer, pH 7.5) and 15 ul of human plasminogen solution (0.5 mg/ml in 0.05 M Tris-Cl, pH 7.5) are mixed together. The tubes are incubated at 37° C. for 15 min, after which 18 ul of NaCl (1.77M in 0.032 M Tris-Cl, pH 7.5) is added. The amount of plasmin generated in the first stage is measured by further addition of 12 ul of plasmin-specific chromogenic substrate, Chromozyme-PL (Boehringer-Mannheim, Germany), 5 mg/ml in water, and the tubes are again incubated at 37° C. for 10 min. After this incubation, 0.4 ml acetic acid (0.2 M) is added to terminate the reaction. The release of yellow-colored 4-nitroaniline is monitored at 405 nm spectrophotometerically. Appropriate dilutions of S. equisimilis streptokinase obtained from WHO, Hertfordshire, U.K. is used as a reference standard for calibration of international units in the unknown preparation. Protein concentration is estimated according to the method of Bradford, M.M., 1976, Anal. Biochem. 72: 248) using BSA as a standard. Bradford's reagent (Biorad Inc., USA) is utilized according to the manufacturer's instructions. For estimating the concentration, protein-samples in phosphate buffer are made to 800 ul. To this, 200 ul Bradfor's reagent is added and is mixed thoroughly. The reaction is maintained at room temperature for 5 min and absorbance at 595 nm is monitored. The specific activity for PG activation (I.U./mg protein) of an unknown preparation of SK or SK-FBD is thus determined from the SK assay and protein estimation data. 7. Fibrin clot assay for SK: This test is performed to determine the clot lysis ability of any thrombolytic drug, such as streptokinase, urokinase or tissue plasminogen activator, and is adapted from British Pharmacopia (1980 edition).

Reagents: (i) 100 mM citrate phosphate buffer. pH 7.1 containing 0.8% BSA (referred to as buffer-1). (ii) Bovine fibrinogen (Cohn Fraction-I, obtained from Sigma Chemical Co., St. Louis, USA), 2.5 mg/ml prepared in buffer-1). (iii) Bovine thrombin (obtained from Sigma as a lyophilized powder). Stock solution of SK, 500 I.U./ml, prepared in sterile water and stored in aliquots of 50 ul each at −70° C. Before use, one aliquot is thawed and diluted to 50 I.U./ml in buffer-1. (iv) Human plasminogen (Boehringer Mannheim, Germany) stock 1 mg/ml, prepared in sterile water. Stored in aliquots of 100 ul each at −70° C. (v) Standard SK (from W.H.O., obtained from Dr. P.J. Gaffney, Division of Haematology, N.I.B.S.C., Blanche Lane, Potters Bar, Hertfordshire, EN 6 3QG, U.K.). The standard SK vial is composed of 700 international units of SK (in lyophilized form alongwith stabilizers). A complete vial should be dissolved in 700 ul of sterile dist. water to obtain a concentration of 1000 I.U./ml. The dissolution should be carried out either at 4° C. or by keeping all the solutions on ice. The dissolved SK is then aliquoted into convenient sizes and stored at −70° C. Prior to carrying out clot lysis assay an aliquot of 1000 I.U/ml (stock) is thawed and diluted further in cold buffer-1 on ice. Dilutions (A to D, below) are prepared serially in the following way using a new pipette tip for each transfer. A. 10 ul of stock+990 ul of buffer-1=10 I.U./ml. B. 500 ul of A+500 ul of buffer-1=5 I.U./ml. C. 500 ul of B+500 ul of buffer-1=2.5 I.U./ml. D. 500 ul of C+500 ul of buffer-1=1.25 I.U./ml.

(All dilutions are tempered at 37° C. prior to use in the clot test as are the other solutions to be used.)

Two hundred ul of each dilution is used in the clot lysis reaction mixture. One unit of SK (present in 200 ul of SK dilution B) is just sufficient to lyse a standard fibrin clot in approximately 5 min at 37° C.

Clot lysis test protocol: (a) Preparation of clot (negative control): During each step, the contents of the tube are gently mixed.

Step 1: add 450 ul of buffer-1 to a small glass tube (0.8 mm internal diameter).

Step 2: add 50 ul of bovine thrombin (50 I.U./ml) solution to the tube.

Step 3: add 100 ul of 1 mg/ml plasminogen to the solution in tube.

Step 4: add 400 ul of 2.5 mg/ml fibrinogen to the solution in tube.

Immediately after step 4, the tube is kept at 37° C. in a water bath without shaking. A standard clot forms within 30-40 seconds. The I.U./ml in the unknown is determined in a similar manner after appropriate dilution.

B) Clot lysis with thrombolytic agent (SK): When clot lysis is to be performed using standard SK, all the steps i.e. 1, 2 and 3 are carried out as described above, except that at step 1, only 250 uL of buffer-1 is added. Also, at step 4, 200 ul from the appropriate dilution of SK containing 1-2 units (as described under Reagents, above) is premixed with 400 ul of fibrinogen solution in a separate eppendorf tube, and rapidly equilibrated to 37° C. in water bath. This mixture is then added to the clotting reaction at step 4, described above. The tube is then incubated as previously. A clot is formed in the same or lesser time as above, but is now followed by its lysis. The time for complete lysis is noted down using a stop watch. The time for lysis depends upon the amount of SK used in the mixture. Lysis time by a particular unit of standard SK (i.e. lysis time of 5 min by 1 I.U. of SK) is taken as a standard. The unknown preparation of SK should be diluted appropriately to obtain a lysis time of approximately 5 min, which can then be used to calculate the units of SK present in that unknown preparation. 8. Kinetic assays for determining the HPG activation by SK or SK-FBD chimeras: A one-stage assay method (Shi, G.Y., Chang, B.I., Chen. S.M., Wu, D.H. and Wu, H.L., 1994, Biochem. J. 304:235. Wu, H.L., Shi, G.Y., and Bender, M.L., 1987, Proc. Natl. Acad. Sci. 84: 8292. Wohl. R.C., Summaria, L., and Robbins, K.C., 1980, J. Biol. Chem. 255:2005). was used to measure the activation of HPG by SK or SK-FBDs. Varying concentrations of either SK or SK-FBD chimeric protein (10 nM-200 nM) were added to 100 ul-volume micro-cuvette containing 1 uM of HPG in assay buffer (50 mM Tris-Cl buffer; pH 7.5, containing 0.5 mM chromogenic substrate and 0.1 M NaCl). The protein aliquots were added after addition of all other components into the cuvette and bringing the spectrophotometric absorbance to zero. The change in absorbance at 405 nm was then measured as a function of time in a Shimadzu UV-160 model spectrophotometer. 9. Assay for determining the steady-state kinetic constants for HPG activator activity of SK and SK-FBD constructs: To determine the kinetic parameters for HPG activation, fixed amounts of SK or SK-FBD(4-5), 1 nM, were added to the assay buffer containing various concentrations of HPG (ranging from 0.035 to 2.0 uM) in the 100 uL assay cuvette as desribed above. The change in absorbance was then measured spectrophotometrically at 405 nm for a period of 30-40 min at 22° C. The kinetic parameters for HPG activation were then calculated from inverse, Michalis-Menton, plots by standard methods (Wohl, R.C., Summaria, L., and Robbins, K.C., 1980, J. Biol. Chem. 255:2005). 10. Radioactive fibrin clot preparation: 50 uL ul of (2.5 mg/ml) cold fibrinogen was mixed with 50 ul (9×10⁵ cpm) of ¹²⁵I-labelled fibrinogen (specific activity 8×10⁵ cpm/ug of fibrinogen) and added to the mixture of 1.1 uM HPG and 0.25 units of human/bovine thrombin in 0.1 M citrate phosphate buffer, pH 7.5 containing 0.8 percent BSA in a total volume of 1 ml in a glass tube (1.3×12 cm). The clot was formed by incubating the mixture at 37° C. for 2 min. The clot was then washed thrice with 2 ml of TNT buffer (50 mM Tris-Cl buffer, pH 7.5, containing 38 mM NaCl and 0.01 percent Tween-80) for 2 min at 37° C. As required the non-radioactive fibrin clots were prepared by omitting ¹²⁵I-labelled fibrinogen from the clotting mixture. 11. Clot lysis in the presence of human plasma: ¹²⁵I-fibrin clot lysis was carried out in the presence of 2 ml citrated human plasma containing different concentrations of either SK or SK-FN (ranging from 100 to 200 nM) at 37° C. The reaction tubes were rotated slowly at 37° C. and 0.1 ml aliquots were removed at regular intervals to measure the soluble ¹²⁵I-fibrin degradation products by measuring the amount of radioactivity released using a gamma counter. The total radioactivity of each clot was determined by measuring the radioactivity of the respective tube before taking out any aliquots. 12. Clot lysis in the presence of human fibrinogen: ¹²⁵I-fibrin clot lysis was also carried out in the presence of various concentrations of human fibrinogen (ranging from 1 to 4 mg/ml) containing 100 nM of either SK or SK-FN. Clot lysis was also performed in the presence of fixed fibrinogen concentration (2 mg/ml) and different concentrations of SK or SK-FBD protein construct (ranging from 50 to 200 nM). The reactions were incubated at 37° C. with gentle shaking and the release of ¹²⁵I-fibrin degradation products as a function of time was measured as described previously.

EXAMPLES Example 1

High Level Intracellular Expression of Biologically Streptokinase in E. coli.

In order to express native-like, full-length S. equisimilis strain H46A Streptokinase intracellularly in E. coli the SK-encoding polynucleotide block was transferred from the plasmid vector construct pJKD-55 by digesting with Nco I and Sal I restriction enzymes (R.E.) which liberated the SK open-reading-frame (ORF). Plasmid pJKD-55 contained the streptokinase gene which was isolated from Streptococcus sp. (ATCC 12449), also referred to conventionally in the scientific literature as S. equisimilis strain H46A, by known procedures earlier reported for the molecular cloning of SK gene and its expression in heterologous hosts such as E. coli (Malke, H. and Ferretti, J.J., 1984; Proc. Nat'l Acad. Sci. 81: 3557; Pratap, J., Kaur, J., Rajamohan, G., Singh, D., and Dikshit, K.L., 1996; Biochem. Biophys. Res. Commun. 227: 303). The latter publication desribes the procedures by which the SK gene was cloned in E. coli plasmids, such as pJKD-8 and pJKD-55 used herein (see below).

The DNA segment liberated from pJKD-55 by R.E. digestion was then cloned into plasmid pET-23(d) (see FIG. 8 for map of this plasmid) which had also been treated with the same enzymes (Nco I and Sal I) to obtain cohesive ends compatible with those of the SK gene (see FIG. 9 for the scheme used for this purpose). This vector contained an initiation codon in-frame with the Nco I site of pET-23(d). Upon ligation, the SK open-reading-frame could be recreated, but one modified at the N-terminal end, together with an additional ATG at the 5′ end emanating from the re-formed Nco I site.

The construction of pET23(d)-SK was carried out as follows. Approx. 3 ug each of pET23(d) and pJKD-55 plasmid DNAs were digested (separately) with 20 units each of Sal I (37° C. for 6 h), followed by 15 units each of Nco I in 20 ul reactions at 37° C. for 10 h. After stopping the reactions by heat treatment (65° C., 10 min), followed by phenol-chloroform extraction and ethanol precipitation of the DNA, the digests were run electrophoretically on a 1.2% agarose gel to isolate the needed DNA fragments i.e. insert, carrying the SK gene from pJKD-55, and the linearized vector pET23(d) [see FIG. 9]. The respective fragments were purified from the gels using the Prep-A-Gene DNA purification kit of BioRad Inc., Calif., USA. The insert and double-digested, linearized vector DNAs were then ligated at an approx. 3:1 molar ratio (˜350 ng of vector and 400 ng of the insert liberated from pJKD-55) in a 20-uL reaction using standard ligation conditions at 16° C. for 12 h. After this duration, the ligase was heat inactivated (60° C., 15 min) and one-fifth of the ligation reaction was directly used to transform E. coli XL-Blue electrocompetent cells using the following electroporation conditions with 2 mm internal diameter electroporation cuvettes (obtained from BioRad Inc., Richmond, Calif., USA): voltage, 2.5 KV; resistance, 200 Ohms, and capacitance 25 uF. Six transformants were picked up from Amp-LB plates on which the transformed cells were plated at various dilutions. Individual colonies were inoculuated into 10 ml LB-Amp media to prepare plasmid DNA by standard methods. The isolated plasmids were then screened electrophoretically on the basis of molecular size to identify the positive clone/s. All six clones were positive by this criterion. In order to express full-length SK containing all of the amino acid residues of mature S. equismilis SK (FIG. 3), the native N-terminal was repaired using a synthetic “cassette” approach (refer to FIG. 10 for the scheme followed for the repair of the SK gene). The portion of the repaired SK gene at the 5′ end in pET23(d)SK was obtained through PCR using the primers RG-6 and RG-7 with the following sequence and target specificity.

RG-7 (forward primer) 5′-ATT GCT GGA CCT GAG TGG CT-3′ (SEQ ID NO:25) (specific for the first seven codons of the SK gene; Cf FIG. 11) RG-6 (reverse primer) 5′-TGG TTT TGA TTT TGG ACT-3′ (SEQ ID NO:26) (specific for codons 57–62 of SK gene)

The PCR was carried out using as the template, plasmid pSKMG-400, which contained the DNA sequences coding for full-length native SK of Streptococcus sp. (ATCC 12449), also referred to as S. equisimilis H46A as described earlier. This plasmid was constructed by cloning the Nco I-Sal I fragment obtained from pJKD-55 followed by T4 DNA polymerase-catalyzed fill-in of the two ends (to obtain blunt ends) and cloning at the Eco RV site of plasmid BlueScript KS⁻ (Stratagene Inc., WI, USA). The two PCR primers were designed to amplify the N-terminal portion of the native SK gene upto a unique restriction site in the gene which could be utilized for recloning the amplified PCR product back into pET23(d)-SK for expression of protein. Moreover, the 5′ end of the RG-7 primer started with ATT, coding for Ile, the first residue of the mature SK-encoding DNA (or gene), so that the PCR-amplified SK-encoding polynucleotide DNA segment could dock in-frame with the nucleotides ATG, formed at the NcoI-cut and refilled end of the expression vector, thus juxtaposing the initiation codon in-frame for the repaired SK ORF. The following PCR conditions were used for the amplification reaction (100 uL total): approx. 10 ng pSKMG-400 as template, 20 pmol each of the RG-6 and RG-7 primers, 1 ul (2.5 units) of pfu DNA polymerase (Stratagene Inc.), 200 uM of each dNTP's, 10 uL of the standard buffer (10× conc. provided by the Stratagene Inc.). The following cycling parameter were used: ‘hot start’ for 5 minutes at 92° C., denaturation at 92° C. for 1 min, annealing at 50° C. for 1 min and extension at 72° C. for 1 min. A total number of 30 cycles, and a final extension of 10 min at 72° C. for allowing the completion of any of the incomplete amplified products, were provided. The PCR showed a single band of 160 bp as evidenced by electrophoresis on a 1.2% agarose gel. For cloning the PCR product into pET23(d)-SK vector, approx. 10 ug pET23(d)-SK vector was digested with 25 units of Ncol restriction enzyme in a 100 ul reaction using the buffer (NEB-4) supplied by New England Biolabs, Inc., and by incubating at 37° C. for 6 h. The completion of Ncol digestion was checked by loading 5 ul of the reaction mixture on a 0.7% agarose gel. After confirming the digestion, the NcoI site was filled-in (i.e. made blunt ended) using T4 DNA polymerase in the presence of all four dNTPs in a 85-ul reaction as follows. Seventy five ul of above-mentioned Nco I digestion mixture was supplemented with 4 ul DTT (100 mM stock), 4 ul dNTP's from a dNTP stock (2 mM), and 2000 Weiss units of T4 DNA polymerase. The reaction was incubated at 37° C. for 1 h after which it was stopped by adding EDTA (10 mM final conc.) and heating at 75° C. for 10 min. The DNA was then ethanol-precipitated. The precipitated DNA was dissolved in 40 ul TE and was digested with Afl II restriction enzyme in a 60-ul reaction at appropriate reaction conditions as recommended by the supplier. Separately, 40 ul of the PCR-amplified DNA reaction, prepared using pSKMG-400 vector as substrate to supplement the deleted portion of the SK gene, was also digested with Afl II restriction enzyme, followed by running on low melting agarose gel (1%) to separate the vector and inset DNA pieces [the insert contained a blunt end, and an Afl II-site compatible cohesive terminus at the other end, thus making it suitable for facile ligation with the vector, which had been similarly treated with Nco I, followed by a fill-in reaction with T4 DNA polymerase to obtain a blunt end, followed by a digestion with Afl II]. The required pieces of DNA were isolated from the electrophoresis gels as small agar blocks after visualization under trans-illuminated UV radiation, and were purified from the agarose by beta-agarase enzyme. One unit of beta-agarase per 100 ul of agarose gel approximately in the 1× beta-agarose buffer (New England Biolabs Inc.) was employed to digest the agarose and to purify the DNA according to the protocol recommended by the supplier (New England Biolabs Inc., USA). The purified DNAs were quantitated and vector and insert were ligated in a 1:5 molar ratio in a 20 ul reaction, carried out at 16° C. for approx. 18 h. For the ligation reaction, 2 ul of 10× ligase buffer, 1 ul of 10 mM rATP stock, and 2000 Weiss units of T4 DNA ligase were used. The DNA from the ligation mixture was precipitated with n-butanol, and used directly to transform electrocompetent E. coli XL-Blue cells. The transformation mixture was plated on LB-Amp plates. The positive clones (repaired pET23(d)SK) were screened from the wild-type background on the basis of Nco I digestion (the insertion of the PCR amplified segment in the vector would result in the loss of the Nco I site). Two of the clones (pETSK-NTRN, for ‘N-terminally repaired, native’) obtained after this screening were further confirmed using Sanger's method of nucleotide sequencing; which showed complete fidelity with the known full-length native sequence of the S. equisimils SK-encoding DNA (Cf. FIG. 11) except the presence of an extra ATG codon at the 5′-end of the ORF, and no mutation/alteration at the upstream promoter regions or downstream sequences in the plasmid could be observed. DNA from these confirmed clones were then transformed into E. coli BL-21 strain, and expression of intracellular SK in liquid culture was examined after induction with IPTG according to the protocol described earlier, essentially by analyses of cell-lysates on SDS-PAGE. However, no band corresponding to standard SK was visible on SDS-PAGE. The possibility of the presence of low levels of SK was then checked by Western Blotting analysis of the lysates as it is a more sensitive method when compared to a direct examination of the SDS-PAGE gels by Coomassie staining. In this case, indeed a faint band corresponding to the position of standard SK on the Western blots could be clearly discerned, which showed that the levels of expression of the native SK gone was poor.

The possibility that the sequences in the native SK-encoding DNA polynucleotide block corresponding to the N-terminal residues could be forming strong secondary structure/s in the encoded mRNA transcripts that might be hindering the expression was examined through computer-assisted analysis using the program DNASIS (version 5.0). This unambiguously demonstrated that the potential for forming highly stable secondary structure by the N-terminal end of the SK gene was appreciably strong (free energy approximately −10 Kcal/mol; see FIG. 12A). Translationally silent mutagenesis of the gene at its 5′ end was then carried out to disrupt and/or reduce this secondary structure by replacement of GC rich codons (that are more likely to promote secondary structure-formation in mRNA transcript) with AT-rich codons, wherever possible. Through this procedure several sequence/s, altered specifically at the 5′-end and possessing lowered stability (−6 to −5 Kcal/mol) as compared to that of the native sequence, were obtained. One of these sequences, that resulted in maximal destabilisation of structure-forming potential, to approx. 5 Kcal/mole (FIG. 12B), was chosen for the expression studies.

The preparation of an expression vector containing a full-length, native SK-encoding polynucleotide segment but one with a modified (i.e. non-native) DNA sequence at its 5′-end with less structure-forming potential was carried out as shown schematically in FIG. 13 using a combination of synthetic DNA cassette incorporation and PCR-based strategy. The alternate sequence to be incorporated at 5′-end of the SK gene was provided through two homologous synthetic oligonucleotides (SC-I and SC-II, complementary to each other except for overhangs at the end), whose sequence is shown below. Also indicated in bold type are the altered nucleotides which resulted in a lowering of structure forming potential in the 5′-end of the SK gene.

SC-I 5′-C ATG ATA GCT GGT CCT GAA TGG CTA CTA GAT CGT CCT TCT GTA AAT AAC AGC C-3′ (SEQ ID NO:13) (Partial NcoI site) SC-II 5′-AA TTG GCT GTT ATT TAC AGA AGG ACG ATC TAG TAG CCA TTC AGG ACC AGC TAT-3′ (SEQ ID NO:14) (Partial MfeI site)

These carried two new restriction sites (NcoI and Mfel), introduced by silent mutagenesis using the computer program GMAP (Cf. Raghava and Sahni, 1994, BioTechniques 16: 1116-1123) without altering the amino acid sequence encoded by this segment of DNA so as to facilitate the cloning of the repaired SK-encoding DNA into the expression vector, pET23(d)-SK (see FIG. 13 for the overall cloning scheme for reconstruction of the N-terminal region of S. equisimilis SK-encoding DNA). The alterations were carried out in two stages, as depicted schematically in FIG. 14. In Stage I, a translationally silent restriction site (Mfe I) was engineered close to the N-terminal end of the SK gene (overlapping codon numbers 17 and 18 in the native SK sequence; see FIG. 3) since no unique site close to the N-terminal end was available for incorporating a synthetic DNA piece for purposes of altering this region in the plasmid. An upstream PCR primer (termed ‘Mfe I primer’) incorporating this potential Mfe I site (underlined in the sequence of the primer) was synthesized with the following sequence.

Mfe I primer: 5′-C-AGC-CAA-TTG-GTT-GTT-AGC-GTT-GCT-3′ (SEQ ID NO:15)

A synthetic oligonucleotide containing an Afl II site (termedRG-6, which has been described before) was used as the downstream primer.

These two primers were utilized for the amplification of the SK sequences encoding the N-terminal region using pfu DNA polymerase. The following reaction conditions and cycling parameters were used. Pfu polymerase buffer (Stratgene Inc.), 200 uM each of the dNTP's, MfeI and RG-6 primers: 20 pmol each, pET23(d)-SK vector as template (2 ng), Pfu polymerase 1 ul (2.5 units), total reaction volume 100 ul. A ‘hot start’ was given for 5 min at 95° C., followed by denaturation for 1 min at 95° C., annealing for 1 min at 45° C., and extension for 1 min at 72° C. A final extension at 72° C. for 10 min was also incorporated in the program. As expected from theoretical considerations, a ]14]-bp long SK region was amplified. The PCR product was phenol-chloroform purified and precipitated using isopropanol after adjusting the salt concentration to 0.3 M with 3 M NaOAC. The precipitated product was dissolved in 25 ul sterile dist. water and kinased in a 30-ul reaction, after adding 3 ul Multicore buffer (Promega Inc., WI. USA), 1 ul (10 units) of T4 PNK (Promega) and 1 ul rATP (10 mM stock). The reaction mixture was incubated at 37° C. for 2 h and then stopped by heat-inactivating at 65° C. for 20 min, and the DNA purified using phenol-chloroform and precipitated with 2 volumes of isopropanol. The pBluescript II KS(−) vector was digested with EcoRV restriction enzyme and then dephosphorylated using CIAP using a standard protocol. Both the kinased PCR product and dephorphorylated pBluescript II vector were quantitated by A₂₆₀ measurements in a 100-uL cuvette, and the vector and insert DNAs were ligated in 1:10 molar ratio of vector: insert by taking 590 ng vector and 280 ng insert in a 20 ul reaction after adding appropriate amount of ligase enzyme (approx. 500 Weiss units) and ligase buffer containing rATP. The ligation reaction was incubated at 16° C. overnight. The ligation mixture was heat inactivated (65° C., 30 min), the DNA was butanol-precipitated, and approx. one-fifth electroporated into E. coli XL-Blue electrocompetent cells. The transformants were screened by plating them on LB-Amp plates. Ten transformants were picked up and inoculated for minipreparation of plasmid DNA. The minipreps were then digested with MfeI and AflII enzymes sequentially to identify the positive clones containing the 141 bp insert. Unmodified pBluescript was kept as control. All the transformants were found to be positive by this criterion. This construct was inbelled as p(MfeI-AflII)-SK.

Stage-II: The oligos SC-I and SC-II in equimolar amounts (approx. 270 ng each) in 25 uL were annealed by cooling their mixture from 80° C. to room temperature slowly. Approximately 5 ug of pET 23(d)SK and 10 ug p(MfeI-AflII)-SK vectors were digested with Afl II/Nco I and MfeI/AflII, respectively, for vector and insert preparations. Twenty five units each of MfeI and AflII were used for vector preparation and 50 units were used for insert preparation. The enzymes were added in two shots of 12.5 units and 25 units in each of the reactions. The pET23(d)-SK vector was digested in a 60 ul reaction, and p(MfeI-AflII)SK was digested in a 100-ul reaction. The pET23(d)-SK digestion mixture was run on a 1% low melting agarose gel for vector preparation and the p(MfeI-AflII) SK digestion mixture was run on a 2% agarose gel for isolating the 115 bp insert. Both the vectors and insert bands were cut out from the agarose gel and were purified using beta-agarase and quantitated. Then, a mixture of Nco I and Afl II digested pET23(d)-SK vector, annealed SC-I and SC-II oligos, and Mfe I-Afl II insert of p(Mfe I-Afl II)-SK vector were ligated in a 3-piece ligation reaction in a 1:7:5 molar ratio in a 20 ul reaction (see FIG. 13). In the actual reaction, approx. 660 ng of the vector, 92 ng of the insert and 60 ng of the annealed oligos were taken. The mixture was ligated by adding 2000 Weiss units of ligase into the reaction. The reaction was incubated at 16° C. overnight. The ligation mixture was n-butanol-precipitated, dried, redissolved in 10 uL TE and approx. one-third used to transform E. coli XL-1 Blue electrocompetent cells. The transformants were screened on LB-Amp plates, Ten transformants were picked and inoculated for preparation of mipreps. All the minipreps alongwith pET23(d)-SK as control were digested with Nco I enzyme to search for the positive clones. Only one clone, as well as pET23(d)-SK, gave digestion with Nco I which indicated that the remaining 9 clones were positive for the desired construct. One of the clones was then completely sequenced by automated DNA sequencing using Sanger's dideoxy method, which showed that the N-terminal region was now full-length i.e. encoded the native SK sequence plus a N-terminal methionine, containing exactly the sequence expected on the basis of the designed primers, SC-I and SC-II with the altered codons at the 5′ end compatible with potential for secondary structure reduction in the mRNA transcripts(see FIG. 14). In addition, the DNA sequencing established that no other mutation was inadvertantly introduced in the SK ORF in during the reconstruction protocol. This plasmid vector-construct, termed as pET23(d) SK-NTR (N-terminally reconstructed) has been deposited in the Microbial Type Culture Collection, Chandigarh, India (MTCC), with the accession No. BPL 0017. The plasmid DNA from this clone was then transformed into E. coli BL-21 DE3 strain for expression studies. The E. coli BL-21 cells were grown in liquid culture and induced with 2 mM IPTG at an OD₆₀₀ of ˜0.6 for the induction of SK, as detailed earlier. The cells were then pelleted by centrifugation and lysed in SDS-PAGE sample buffer and analysed electrophoretically by SDS-PAGE on 10% acrylamide gel. It was observed that the level of SK (47 kD band) was approx. 25-30 percent of the total soluble proteins, a substantial increase compared to the very low expression observed in the case of the construct with the native N-terminus (pET 23(d)-SK-NTRN).

Example 2

Harvesting of Intracellularly Expressed SK From E. coli, Purification of SK Protein, and Characterisation of Highly Pure and Biologically Active SK.

Glycerol stocks of E. coli BL-21 strain harbouring plasmid pET23(d)SK-NTR, maintained at −70 C, were used to prepare a seed culture by inoculating freshly thawed glycerol stock (approx. 100 uL) into 100 ml of LB medium (in a 500 ml conical flask) containing 50 ug/ml of ampicillin. The flask was incubated at 37° C. with shaking on a rotary shaker at 200 r.p.m. for 16 h. This culture was used to seed four 2 L Erl nmeyer flasks each containing 500 ml of the same medium (LB-Amp) using 5% (v/v) of inoculum. The flasks were incubated at 37° C. with shaking (200 r.p.m.) for a duration till the absorbance at 600 nm had reached 0.5-0.6 (˜2 h after inoculation). At this time, IPTG was added to the cultures to a final conc. of 2 mM and incubation, as before, continued for a further 3 h. The cultures were then chilled on ice and processed for the next step immediately. The cells from the culture media were harvested by spinning them down by centrifugation at 6000×g in a GS-3 rotor (Servall) for 30 min at 4° C. The supernatants were discarded and the combined cell-pellets carefully resuspended by vortexing in 65 ml of lysis buffer containing a chaotropic agent for effecting release of the cellular contents. The composition of the cell lysis buffer was as follows (final concentrations are given): 6 M guanidine hydrochloride and 20 mM sodium phosphate buffer, pH 7.2.

The E. coli cell suspension was shaken gently on a rotary shaker at 4° C. for 1 h to effect complete cell lysis. The lysate was then subjected to centrifugation at 4° C. for 15 min at 9000 r.p.m. The clear supernatant (containing approx 300 mg total proteins as determined by the Bradford method) was then processed further, as follows (all subsequent steps were conducted at 4° C., and all buffers and other solutions used were also maintained at 4° C.). The supernatant was diluted 6-fold in which the conc. of Gdn.HCl was 1 M; simultaneously, aliquots of a stock solution (0.5 M) of sodium phosphate buffer, pH 7.2, n NaCl (stock conc. 5 M) were added to obtain 20 mM and 0.5 M with respect to sodium phosphate and NaCl, respectively, in the diluted cell lysate supernatant (final volume 200 ml). The mixture was gently swirled for a few minutes, and then loaded onto a 100 ml bed volume (4 cm internal diameter) axial glass column for hydrophobic interaction chromatography (HIC) on phenyl-agarose-6 XL (Affinity Chromatography Ltd., Isle of Man, U.K.) coupled with an automated liquid chromatography work-station (model Biocad Sprint, Perseptive Biosystems, MA, USA) capable of continuous monitoring of effluents at two wavelengths simultaneously, and formation of predefined gradients for elution. The column was pre-equilibrated width 0.5 M NaCl in 20 mM sodium phosphate buffer, pH 7.2 (running buffer) onto which the bacterial cell lysate was loaded at a flow rate of 85 ml/h. The flow-through was collected, and the column washed with running buffer (400 ml total) at the same flow rate, followed by the same volume of running buffer devoid of NaCl (washing steps). The SK was then eluted with dist. water (pH 7.0) at a slower flow rate (35 ml/h). All the effluents were collected in fractions (25 ml each) and the SK activity as well as protein content in each fraction was determined. Virtually all of the loaded SK activity was found to bind to the column, less than 5% of the total activity being found in the flow-through and washings. Approximately 85-90% of the loaded SK activity was recovered at the dist. water elution step. SDS-PAGE analysis showed the presence of a predominant band of 47 kD migrating alongwith native SK (purified from S. equisimilis H46A) run as standard. The SDS-PAGE as well as the activity analysis showed the SK to be 85-90% pure at this stage when compared to the unpurified cell lysate. The SK in the dist. water elute was then made 26 mM in sodium phosphate, pH 7.2 (running buffer) and loaded at a flow rate of approximately 300 ml/h onto DEAE-Sepharase Fast Flow (Pharmacia, Uppsala, Sweden) packed in a 1.6×20 cm axial glass column pre-equilibrated with the running buffer. The column was then washed with 200 ml of the same buffer, following which it was developed with a NaCl gradient (0-0.6 M) in running buffer (pH 7.2). All eluates from the column were saved with an automated fraction collector. Ten-ml fractions were collected, and SK activity as well as protein was estimated in each. Aliquots from each fraction were also analysed by SDS-PAGE to examine the relative purity of the eluted protein. The flow-through and washings were essentially devoid of SK activity, but approximately 80-85% of the loaded SK activity eluded at around 0.35 M NaCl in the gradient as a single symmetrical peak (containing a total of 42 mg protein). The specific activity of this protein was 1.1×10⁵ I.U./mg. On SDS-PAGE, it showed a single band co-migrating with standard natural S. equisimilis SK. A densitometric analysis of the SDS-PAGE gels revealed that the background protein/s in the final purified SK represented less than 2% of the total Coommassie stainable content. The overall SK recovery with the purification process was found to be approx. 65 percent.

The purified recombinant SK expressed in E. coli was characterized physico-chemically by several other criteria in order to compare it with natural SK. By the clot lysis procedure, it showed a specific activity of 105,000 IU/mg, under conditions where natural SK from S. equisimilis strain H46A was found to have a specific activity of 110,000 IU/mg protein. Upon reverse phase high performance liquid chromatography (RP-HPLC) on C-18 columns, both SK types were indistinguishable, showing the presence of a single symmetrical peak at the same position when eluted with a gradient of gradually increasing ACN concentration. By UV spectroscopy, the recombinant SK was found to be identical to the natural SK. The N-terminal amino acid sequence of rSK was found to be identical with that of natural SK, except for the presence of an extra methionine residue at the N-terminus (the sequencing was carried out for 25 cycles).

Example 3

Construction of a Hybrid DNA Polynucleotide Between SK-encoding DNA and Fibrin Binding Domains 4 and 5 Encoding DNA of Human Fibronectin, its Expression in E. coli, Oxidative Refolding, and Purification of Biologically Active Chimeric Protein.

The scheme followed for the construction and expression of a chimeric (hybrid) polynucleotide DNA block formed between the DNA encoding for residues 1 to 383 of SK followed by in-frame joining to the DNA coding for the FBD 4 and 5 of human fibronectin is shown in FIG. 16. A short linker DNA segment, coding for 3 glycine residues, in tandem, between the two polynucleotide-segments was incorporated into the design (termed ‘intergenic sequence’) (see FIG. 15) so as to provide flexibility to the expressed chimeric polypeptide product. In addition, a new terminator codon was introduced at the end of the FBD(4,5) DNA so that the hybrid ORF encoded for a polypeptide ending after the two FBDs. Thus, the design essentially had the following configuration: SK[residues 1-383]-(gly-gly-gly)-[FBD(4,5)]. In addition, a transglutaminase recognition site was also engineered in the gene-design directly after the intergenic sequence so that the expressed, hybrid protein could become covalently cross-linked to the fibrin strands of the clot (FIG. 15). A two-stage PCR-based experimental strategy (FIG. 16) was employed to construct the hybrid polynucleotide. A polynucleotide-block containing the sequence coding for domains 4 and 5 was first selectively amplified using the plasmid pFHMG-60 as template. The latter contained the DNA encoding for all five human FBDs (FIG. 16). This amplification reaction (PCR-I) was carried out with specifically designed forward and reverse primers with the following sequences.

Forward primer (MY 13); 5-CCG GAA TTC GCG CAA CAG ATT GTA CCC ATA GCT GAG AAG TGT TTT GA-3′ (SEQ ID NO:16)         Eco RI Transglutaminase-        hybridizes to upstream FBD(4,5) sequences                 recognition sequence Reverse primer (MY 14); 5′-GGC CTT AAG AGC GCT CTA ACG AAC ATC GGT GAA GGG GCG TCT A-3′ (SEQ ID NO:17) ‘clamp’ Afl II  Eco 47 III stop   hybridizes to downstream FBD(4,5) sequences                      codon Note:- In the above primer sequences, the 5′-non-hybridising sequences (bold) as well as the hybridizing ones, towards the 3′-ends of the primers that are complementary to selected segments of fibronectin FBD(4,5)-encoding DNA sequences are shown. In the 5′-non-hybridizing ends were also incorporated new R.E. sites by ‘silent’ mutagenesis, a transglutaminase(TG)-encoding site and/or stop codon sequences, as indicated above (underlined). The start of the hybridizing sequencesin primer MY-13 correspond to the begining of the sense strand sequence of FBD(4,5), namely residue 150 onwards (refer to FIG. 6 for the amino acid and DNA sequences of the fibrin binding domains of human fibronectin). In case of primer MY-14, the begining of the hybridizing sequence (antisense) correspond exactly to the codon for residue 259 of human fibronectin (Cf. FIG. 6). The ‘clamp’ mentioned in the figure refers to the extra nucleotides added at the 5′ end of aprimer to facilitate the digestion at the nearby R.E. site which, otherwise, is poorly digested when present at or near the end of a DNA fragment generated by PCR. Note: In the above primer sequences, the 5′-non-hybridising sequences (bold) as well as the hybridizing ones, towards the 3′-ends of the primers that are complementary to selected segments of fibronectin FBD(4,5)-encoding DNA sequences are shown. In the 5′-non-hybridizing ends were also incorporated new R.E. sites by ‘silent’ mutagenesis, a transglutaminase(TG)-encoding site and/or stop codon sequences, as indicated above (underlined). The start of the hybridizing sequences in primer MY-13 correspond to the begining of the sense strand sequence of FBD(4,5), namely residue 150 onwards (refer to FIG. 6 for the amino acid and DNA sequences of the fibrin binding domains of human fibronectin). In case of primer MY-14, the begining of the hybridizing sequence (antisense) correspond exactly to the codon for residue 259 of human fibronectin (Cf FIG. 6). The ‘clamp’ mentioned in the figure refers to the extra nucleotides added at the 5′ end of a primer to facilitate the digestion at the nearby R.E. site which, otherwise, is poorly digested when present at or near the end of a DNA fragment generated by PCR.

As described above, the forward primer contained a segment at its 3′ end that was homologous with the 5′ end of the DNA encoding for the FBD(453) sequences, and also contained a 5′ (nonhybridizing) segment that encoded for a TG-recognition site is well as RE sites to facilitate the cloning of the PCR product in a plasmid vector. This plasmid, containing the FBD(4,5) gene-block and additional 5′ sequences was then employed as template for a second PCR (PCR-II) using a set of primers (RG-3 and MY-14). Primer RG-3 was designed so as to contain the other desired elements of the intergenic segment viz., the codons for the gly-gly-gly residues, as well as those encoding for a small segment of SK (see FIGS. 15 and 16) directly after a unique R.E. site (Bsm I) present naturally in the C-terminal region of the native SK ORF (approximately overlapping the codon 377 and 378 of the S. equismilis SK open-reading-frame; Cf. FIGS. 3 and 4). This site was chosen as the common, junction-point between the two polynucleotide blocks (i.e. SK and FBD) to be integrated. Additionally, unique restriction sites flanking the intergenic (i.e. in and around the -gly-gly-gly-) sequences were also designed into the upstream primer through translationally silent mutagenesis that could be exploited to substitute alternate oligonucleotide cassettes at the intergenic region of the hybrid polynucleotide that would provide altered flexibility and/or rigidity characteristics in the expressed polypeptide different from that provided by the (gly)₃ linker (Cf. FIG. 15).

The sequence of primer RG-3 is given below highlighting features incorporated in its design (bold letters denote non-hybridizing segments towards the 5′-end of the primer to distinguish these from the sequence complementary with respect to template DNA).

5′-G AAT GCT AGC TAC CAT TTA GCT GGT GGT GGC CAG GCG CAA CAG ATT GTA CCC-3′ (SEQ ID NO:18)    Bsm I       Bst X          Xcm I  Bal I   segment hybridizing with the (hybridizes to SK gene at                             5′-end of DNA block from PCR-1 codons 376–383)                      (-gly-gly-gly-)  at the TG recognition site

The amplified DNA obtained from PCR-II using primers RG-3 and MY-14 was treated with Bsm I to “dock” it at the Bsm I site in the SK ORF in vector pSKMG400 at one end, and with Eco 47 III (which produces blunt-ends) to facilitate blunt-end cloning at the filled-in Bam HI site present after the SK open-reading-fame (ORF) in the plasmid vector (FIG. 16).

The following reaction conditions and PCR; parameters were used. PCR-I (final reaction conditions in a 100-uL reaction). 20 pmol of each of the MY-13 and MY-14 primers, pFHMG-60 vector as template (1 ng), 200 uM each of the dNTP's, Pfu polymerase 1 ul (2.5 units). Pfu polymerase was added at 94° C. i.e. a hot start for 5 min was given to avoid non-specific amplification. The following cycling conditions were employed: denaturation at 92° C. for 45 seconds, followed by annealing at 60° C. for 1 min, and extension at 72° C. for 1 min. A total number of 30 cycles were given, followed by a final extension for 10 min at 72° C. The reaction yielded a single 360 bp PCR product as seen on a 2% agarose gel alongwith standard PCR markers. The amplified product was then cloned into pBluescript II KS⁻ at the EcoRI site (refer to FIG. 16) which had been introduced in the PCR product as a 5′-overhang. The PCR reaction mixture was purified using standard methods, and then kinased with T4 PNK enzyme. The kinased PCR product was ligated to concatamarize the PCR product in order to internalize the EcoRI site to facilitate cloning of the DNA using the procedure of Jung et al. (Jung, V., Pestka S.B., and Pestka, S. 1990, Nucl. Acids Res. 18:6156). The ligated DNA mixture was then digested with EcoRI followed by electrophoresis on a 2% agarose gel to check the efficiency of the ligation and digestion steps. The band representing EcoRI-digested PCR product was cut out form the gel and purified. Approximately 400 ng of the PCR product was ligated with lug of pBluescriptII (KS⁻) predigested with EcoRI and then dephosporylated. Approximately 2 ul of the ligation mixture was directly used to transform E. coli DH 5-alpha electrocompetent cells. The transformants were selected on LB-Amp plates containing IPTG and X-gal using blue and white colony selection. Ten white transformants were picked and taken up for minipreparation of plasmid. The plasmid DNAs were digested with EcoRI enzyme, and the digests analysed on 1.5% agarose gels. The tansformants releasing 360-hp insert (the size of the PCR product) were taken as positive clones. Nine of the ten clones were found to be positive by this criterion. One of the above clones was then confirmed for the absence of any unexpected mutations by automated DNA sequencing by Sanger's procedure, and used as template for PCR-II employing RG-3 and MY-14 as primers so as to add additional sequences at the 5′ end of amplified FBD sequences in the cloned PCR-I product. The PCR-I had resulted in the addition of a TG recognition site and a stop codon onto the original FBD(4,5) gene-block, whereas the stage-II PCR was carried out to effect the addition of the poly-glycine linker and overlapping SK sequences onto the FBD(4,5) gene-block. The following reaction conditions and cycling parameters were used for carrying out PCR-II. Each of the dNTP's: 200 uM, PCR-I product cloned in pBluescript II (KS⁻) as template (linearized) 260 ng, RG-3 and MY-14 as forward and reverse primers (100 pmol each), 5%

DMSO (v/v), 1 ul Taq DNA polymerase (2.5 units) in a total reaction-volume of 100 ul. Cycling parameters were similar to that of PCR-I except that the annealing temperature was lowered to 58° C. An aliquot (aprox. one-tenth) of the PCR-II was run on a 1.5% agarose gel to check for amplification. As the Taq polymerase does not produce blunt ended PCR products (unlike pfu polymerase) but ones with a single-base overhangs (reference), the PCR product was first filled-in, and then kinased. These two modifications carried out in a single reaction at 22° C. for 30 min using 10 units each of the T4 DNA polymerase and T4 PNK (total volume 85 ul). In addition, 8 mmol dNTP's as well as 1 mmol rATP were added to the reaction (all indicated conconcentrations are final). The reaction was stopped by adding EDTA to 10 mM followed by heating the tube at 70° C. for 10 min. The filled and kinased PCR product was subjected to a phenol-chloroform treatment and precipitated with two volumes of ethanol in the presence of 0.3 M sodium acetate. The pellet was redissolved in 20 ul of dist. water. Approx. 15 ul of this DNA was ligated in order to concatemarize the PCR product. For doing the ligation, 1X Universal Buffer (supplied by Stratgene Inc.), 1 ul (of a 10 mM rATP stock) and 400 weiss units of T4 DNA ligase were added to a 25 ul reaction. The reaction was incubated at 16° C. overnight. The ligase was heat-inactivated at 65° C. for 10 min. The concatamerized PCR product was then first digested with Eco47 III (approx. 20 units) in a 25 ul reaction at 37° C. for 6 h and then the DNA was digested with BsmI enzyme at 65° C. for 6 h after adding ˜20 units of BsmI enzyme in the same reaction. In parallel, the vector pSKMG-400 (approx. 4 ug), containing the SK gene, was digested with BamHI enzyme according to standard protocol and the digested DNA was filled-in using T4 DNA polymerase in the presence of 100 uM dNTP's and 0.5 mM DTT. The reaction was incubated at 37° C. for 1 h. The reaction was stopped by heating the tube at 75° C. for 10 min. Then the BamHI filled vector was digested with BsmI enzyme by incubating at 65° C. for 6 h. The vector was purified by a phenol-chloroform treatment followed by a chloroform-isoamyl extraction, followed by ethanol precipitation of the DNA. Then the Eco47III and BsmI double-digested PCR product and BamHI-digested and filed-in plus BsmI-digested pSKMG-400 vector were ligated (refer to FIG. 16) in 20-ul reaction by incubating at 16° C. for 14 h, after which the ligase was inactivated by heating at 70° C. for 10 min and then the DNA was precipitated with n-butanol. It was then used to transform E. coli XL-Blue electocompetent cells. The transformed colonies were then selected on LB-Amp plates. Ten transformants were picked and screened for the presence of the diagnostic test, namely the release of a 372-bp fragment after digestion with NotI and BamI enzymes, in contrast to a 295-bp fragment from the control plasmid, pSKMG400 since the positive clones contained the additional FBD(4,5) segment Eight clones from ten selected turned out to be positive by this criterion. The positive clones were designated as pSKMG400-FBD(4,5). One of these was subjected to DNA sequencing which confirmed the presence of the expected sequence at the 5′-end, and a complete absence of any other mutation in the rest of the gene-block.

For the expression of the SK-FBD(4,5) hybrid polynucleotide DNA intracellulartly in E. coli, the scheme shown in FIG. 17 a was followed. The BsmI-NotI DNA piece from pSKMG400-FBD4-5 [begining from that encoding for the C-terminal portion of the SK gene and carring the intergenic linker region, the FBD(4,5) segments, and ending after the stop codon for this ORF at the Not I site originating from the multiple cloning site (MCS) of the parent vector] was transferred into plasmid pET23(d)SK-NTR digested with the same restriction enzymes. The digested vector and the DNA segment from pSKMG400-FBD(4,5) (insert) were isolated from 1% agarose gels after beta-agarase digestion, as described earlier, The vector and insert DNA were then ligated by standard procedures using a vector: insert molar ratio of 1:5 (approximately 590 ng of the BsmI/NotI double-digested vector and 250 ng of the BsmI/NotI double-digested insert in a 20-ul reaction). DNA from the ligation reaction was butanol precipitated and directly used to transform E. coli XL-1 Blue electro-competent cells. Transformants were selected on LB-Amp plates. Ten transformants were picked up and taken up for plasmid minipreparation. The miniprep DNAs were digested with BsmI and NotI enzymes, alongwith pSKMG400-FBD(4,5) as control. Three clones gave BsmI/NotI insert equal in size to that of the insert liberated from pSKMG400-FBD(4,5). One of the clone, designated pET23(d)SK-NTR-FBD(4,5) and deposited with MTCC with accession No. BPL 0014, was then fully sequenced by automated DNA sequencing in and around the SK insert (see FIG. 17 b for the gene sequence). All the 3 positive clones were transformed into E. coli BL-21 strain and were induced for the expression of SK-FBD(4,5) hybrid protein using the standard protocol described before. The E. coli BL-21 cells harboring the plasmid pET-SK-FBD(4,5) were induced with 2 mM IPTG at ˜0.60D₆₀₀ and were further incubated for 3 h at 37° C. In parallel, cultures were also grown where IPTG addition was omitted (uninduced controls). Cells from 1.5 ml of the cultures were pelleted down by centrifugation and were directly lysed in 100 ul SDS-PAGE sample buffer. After high-speed centrifugation (8000 g×20 min) to pellet undissolved components, approx. 25 ul of the supernatunt of each of the samples (alongwith lysate from pET-23(d) SK-NTR, as positive control) was loaded onto 10% SDS-PAGE gel and subjected to electrophoretic analysis. The gels showed distinct bands of 57 kD in the IPTG-induced cultures (roughly representing 20-25% of the total Commassie-stained protein bands in the gel), indicating that the hybrid SK-FBD(4,5) fusion protein had been expressed at high levels. In the case of pET23(d)SK-NTR harboring cultures, a band corresponding to 47 kD, the position of native SK, was observed. In parallel, SDS-PAGE gels were subjected to the plasminogen-overlay procedure, which showed distinct zones of clearance by the 57 kD hybrid protein, however, these zones were produced with a distinctly slower rate in comparison to those produced by native SK or the rSK expressed in intracellularly from pET23(d)SK-NTR.

Ten ml of LB-Amp media were inoculated with E. coli BL21 cells harboring pET-SK-FN (4,5) and incubated at 37° C. for 12 h with shaking (200 r.p.m.). This inoculum was used to seed 200 ml of LB-Amp medium, and incubated for 2 h at 37° C. with shaking. At this time, the OD₆₀₀ of the culture was approx. 0.600. The production of SK-FBD(4,5) protein in this culture was then induced by the addition IPTG to 2 mM, and incubation continued for another 3 h at 37° C. with shaking. The OD₆₀₀ had reached 1.2 by this time. The cells were harvested by centrifugation (8000 g×20 min) at 4° C., washed once with ST buffer, and resuspended in approx 14 ml of the same buffer over ice. This cell suspension was then subjected to sonication in the cold (20 sec pulses with 20 sec. gaps; total time 15 min). The lysate so obtained was then centrifuged (10000 g×30 min) at 4° C. The supernatant was carefully decanted into a separate flask. This solution contained approx. 6 mg/ml protein as estimated by Bradford's method using BSA as standard, and had a total of 1.5×10⁴ I.U. of SK activity as measure by the chromogenic peptide procedure (see description of methods, given above). The lysate was then split into two portions of ˜6 ml each to effect either air oxidation or glutathione-mediated oxidation of the SK-FBD(4,5) polypeptide. For the air oxidation, the 6 ml lysate was diluted to a total of 40 ml of solution (reaction mixture A) which contained (final concentrations): Tris-HCl (pH 7.5), 50 mM and NaCl, 150 mM. In reaction B (reoxidation using the reduced-oxidized glutathione buffer), the final volume was also 40 ml, but it also contained [besides NaCl (150 mM) and Tris-Cl (50 mM)], a mixture of GSSG and GSH (1:10 molar ratio, with GSH at 10 mM) and EDTA (1 mM). Both reactions were subjected to gentle mixing at room temperature (24 plus/minus 2° C.) for 10 min and then passed through two separate glass columns each containing 6 ml human fibrin-Sepharose at a flow rate of 20 ml/h in a recycled mode i.e. the effluent was passaged back into the column with the use of a peristaltic pump. After 18 h of passage through the respective columns, the flow of the reaction mixtures was terminated. Each column was then washed with 50 ml of binding buffer (50 mM Tris-HCl, pH 7.5, and 150 mM NaCl) followed by 50 ml each of 2 M urea (in binding buffer), followed by 6 M urea in the same buffer (to effect tightly bound protein). All washings were collected in 10 ml fractions with a fraction collector, and analyzed for protein by Bradford's method, as well as SK activity using chromogenic substrate and human plasminogen as substrates was also determined for each fraction. The total yield of protein in the 6 M urea washings was 280 ug in the case of reaction A (air oxidation), and 380 ug in case of Reaction B (GSG-GSSH mediated refolding). These two pools represented, respectively, the fibrin-binding SK-FBD(4,5) protein obtained a air oxidation or glutathione-catalyzed refolding of the intracellular protein expressed from the plasmidpET23(d)SK-FBD(4,5). The specific activity of both the fibrin-Sepharose binding protein fractions from Reaction A and B were found to be almost identical (2.5×10⁴ IU/mg and 2.1×10⁴ I.U./mg, respectively). The dilute protein factions were concentrated approx. 10-fold with centrifugation in Sartorius centristart filters. The concentrated fractions were then analyzed by SDS-PAGE, with and without reduction with beta-mercaptoethanol. On reducing SDS-PAGE (i.e. with beta-mercaptoethanol treatment of the samples), the reoxidized-refolded SK-(FN4,5), irrespective of the method of reoxidation, showed a single predominant band, but one with higher MW (˜57 kD) as compared to the native SK standard (47 kD) as expected on the basis of the chimeric design of the hybrid gene. Essentially the same patterns were obtained when the SDS-PAGE was conducted without beta-mercaptoethanol, a treatment wherein any of the cystine disulfide (S—S) bridges would not be reduced to cystine —SH groups. This indicated that the refolded molecules contained essentially monomeric intra-molecular S—S bonds, and contained negligible quantities of higher molecular weight (i.e. polymeric) products formed due to inter-molecular S—S bridge formation between the SK (FN4,5) molecules as a result of the reoxidation step. When analyzed by the Ellman DTNB color reaction for thiol groups (Habeeb, A.F.S.A., 1972., Methods in Enzymol. 25:457., Academic Press, New York) these fractions showed the complete absence of any free —SH group, indicating that the oxidation of the original 8 cysteines present in the reduced form of the chimeric polypeptides, to S—S bridges, was complete as a result of the reoxidation/refolding step.

Example 4

Construction of a Hybrid DNA Polynucleotide Between DNA Encoding for SK and FBD Pair 1 and 2, and Cloning and Expression of the Chimeric Polypeptide in E. coli.

The construction of a hybrid between SK and FBD pair 1 and 2-encoding polynucleotide DNA in the same translational frame involved a strategy closely similar to that utilized for hybrid construction between SK− and FBD pair 4 and 5-encoding polynucleotide DNAs (FIG. 18). The essential ‘units’ used in both the constructs were similar i.e., DNA encoding residues 1 to 383 of SK, a short polynucleotide sequence encoding for polyglycine linker between the two DNA polynucleotide blocks, and a transglutaminase (TG) recognition site for cross-linking, removal of the stop codon of the SK gene and introduction of a new stop codon at the end of the FBD segments [either FBD(4,5) or FBD(1,2) etc]. This strategy also exploited the use of the Bsm I site of the SK gene as a common junction-point for the fusion between the SK and FBD(1,2) polynucleotide segments. However, the strategy differed from that employed for constructing SK-FBD(4,5) fusion in that the amplification of the FBD (1,2) domains was carried out in one stage, unlike that of SK-FBD(4,5) wherein two consequetive PCRs with differing 5′-primers were utilized (Example 3). This was because in case of the SK-FBD(1,2) construct a very large primer was not required as a TG recognition site is naturally present in the FN gene just at the begining of the FBD-1 domain (Cf. FIG. 6), thereby obviating the need to engineer a TG site in the upstream primer.

The FBD pair (1,2) was amplified from the plasmid pFHMG-60 (containing all five of the FBD encoding sequences of human fibronectin) with the following tow primers whose sequences arc provided below. Also shown are the 5′-ends containing non-hybridizing sequences (in bold letters) and the incorporated RE sites therein to facilitate cloning and/or docking into the SK gene; the areas hybridizing with the target DNA sequences in the templates are also underlined.

Upstream primer, MY-10                             SK sequence (codons 377–383; Cf. FIG. 3) 5′-G-TAC-GGA-TCC G-AAT-GCT-AGC-TAT-CAT-TTA-GCG-GGT-GGT-GGT CAG-GCG-CAG-CAA-ATG-GTT-3′ (SEQ ID NO:19)          Bam HI      Bsm I                       (-gly-gly-gly-) hybrdizes at thr TG-recogntn.                                                                     site just before the FBD                                                                          sequences Downstream primer, MY-6 5′-GGC-CTT-AAG-AGC-GCT-CTA-TTA-GAT-GGT-ACA-GCT-TAT-TCT-3′ (SEQ ID NO:20)   ‘clamp’ Eco RI Eco 47 II Stop     sequence hybridizing with FBD(1,2)             site            codons        codons 99–104 (Cf. FIG. 6)

The following conditions were used for the PCR: Each of the dNTP's: 200 uM; pFHMG-60 vector as template: 1 ng; MY-10 and MY-6 primers: 20 pmol each; pfu polymerase 2.5 units, 1× pfu polymerase buffer (Stratagene Inc.), and a total reaction volume of 100 ul. A ‘hot start’ was given for 5 min at 94° C. The following cycling parameters were used denaturation at 92° C. for 45 sec, annealing at 50° C. for 60 sec, and extension at 72° C. for another 60 sec. A total of 30 cycles were given, after which a final extension was provided at 72° C. for 10 min. The amplification of the SK-FBD (1,2) hybrid cassette was checked by loading one-tenth of the reaction mixture on a 2% agarose gel. This demonstrated that the expected DNA (369 bp) was satisfactorily amplified in the absence of any background bands. The amplified PCR product was then cloned into pBluescriptII KS(−) after purification through Qiagen PCR-purification column using the manufacturer's protocol. Approximately 2 ug of pBluescriptII KS(−) vector was digested with 10 units of Sma I restriction enzyme in 1× NEB-4 buffer in a 20-ul reaction by incubating the digestion mixture at 25° C. for 12 h. The enzyme was inactivated by heating at 55° C. for 5 min and the linearized plasmid DNA was purified after electrophoresis on a 1% agarose gel. Then, 150 ng of the Smal-digested vector was ligated with approx. 120 ng of the purified insert DNA (PCR product) in a 25-ul reaction after adding 2.5 ul of 10× (stock) ligase buffer (New England Biolabs Inc., MA, USA), 1 ul of 10 mM rATP stock and 400 weiss units of T4 DNA ligase. The ligation was done by incubating the reaction tube at 16° C. for 12 h. After the ligation, the ligase was inactivated by heating at 70° C. for 10 min. The DNA in the ligation mixture was precipitated with n-butanol and then dissolved in 20 ul of dist. water and approx. one-third used to transform E. coli XL-Blue electrocompetent cells (Stratgene Inc., USA) by electroporation. Transformants were selected by plating on LB-Amp plates. Miniprep plasmid DNA was prepared from eight selected clones and analysed by agarose gel electrophoresis. The plasmid DNAs of the transformants were run alongwith pure pBluescript II KS(−) to identify positive clones with larger molecular weight (MW), signifying the presence of the PCR-generated inset DNA. Three transformants were found to be moving slower than the pBluescript DNA on 1.2% agarose electrophoresia. To further confirm that these contained the DNA insert, their plasmid DNAs were digested with EcoRI and BamHI enzymes since EcoRI and BamHI were two of the sites that were introduced in the PCR product during amplification. This showed that a 370-bp fragment, corresponding to the size of the PCR product was liberated, clearly establishing that these clones contained the desired cassette. This was finally confirmed by automated DNA sequencing by the Sanger dideoxy chain-termination method which showed a complete correspondence with the sequence expected on the basis of the primers and the target DNA viz., FBD(1,2) alongwith a short stretch at its 5′-end carrying SK-specific and intergenic sequences. The sequencing also established the absence of any other mutation in the amplified DNA. The cassette subcloned in pBluescriptII KS(−) was then transferred into the SK-containing vector, pSKMG400, in order to fuse it in-frame with the SK ORF utilising the common Bsm I site. For cloning the SK-FBD(1-2) hybrid cassette into pSKMG400 vector, both vector and insert DNAs were first digested with BamHI. Roughly 2 ug of the pBluescript-FBD(1,2) and 4 ug of the pSKMG400 were digested with 8 units each of the BamHI enzyme in a 30 ul reaction utilizing buffer D of Promega. The tubes were incubated at 37° C. for 6 h. A small aliquot was run on a 0.7% agarose gel to check for the digestion. After confirming completion of digestion, the reaction was stopped by adding 0.1 volume of 100 mM EDTA. The digested samples were loaded onto 0.8% agarose gel and the desired fragments were cut out as agarose blocks. The DNA was extracted by treatment with beta-agarase as detailed before, and quantitated. Ligation reaction was set up between double-digested vector and the fragment containing the SK-FBD(1,2) cassette using ˜200 ng of the vector and 30 ng of the fragment, 4 ul of the ligase buffer, 4 ul of 10 mM rATP, and ˜600 Weiss units of ligase in a total volume of 40 ul. The ligation reaction was incubated at 16° C. for 12 h. The ligase was inactivated by heating the tube at 70° C. for 10 min then the ligated DNA was precipitated using n-butanol, air-dried and dissolved in a small volume of sterile distilled water. For the transformation step, approx. 100 ng of the ligated DNA was used to transform E. coli XL-1 Blue electrocompetent cells which were plated on LB-Amp plates. Five colonies were picked up and used for plasmid minipreparations. The plasmid DNAs were digested with Afl II and Eco47 III restriction enzymes separately. pBluescript FBD(1,2) and pSKMG400 vectors digested with the same enzymes were kept as controls. The digestion mixtures were run on a 0.7% agarose gel along with double-digested controls. Two clones showed linearization upon Eco47 III digestion. The pBluescript FBD(1,2) control also showed linearization with Eco 47 III digestion, as expected. However, the positive clones were of higher molecular size due to the presence of SK. The pSKMG400 did not show any digestion with Eco 47 III enzyme. The positive clones also gave out an insert upon AflII digestion, as anticipated from the known presence of a single Afl II site SK and another in the FBD(1,2) segment.

For the expression of the hybrid SK-FBD(1,2) polypeptide, the Bsm I-Not 1 fragment from pSKMG400-FBD(1,2) was transferred into pET23(d)SK-NTR at the same site (see FIG. 19 a). Approximately 10 ug of pSKMG400-FBD(1,2) plasmid DNA was digested with 15 U of Not I enzyme in NEB-3 buffer supplemented with 1× BSA by incubating at 37° C. for 6 h in a 60-ul reaction. A second addition of Not I enzyme was again made and the reaction mixture was further incubated for another 6 h. A small aliquot was removed to check for the completion digestion by running an agarose gel. After the NotI digestion, the DNA was precipitated with ethanol and sod. acetate (0.3 M), redissolved in 20 ul of dist. water and digested with 20 U of BsmI enzyme in NEB-2 buffer in a 80-ul reaction at 65° C. for 14 h after overlaying the reaction mixture with 50 ul of mineral oil to avoid evaporation. Similarly, in parallel, approx. 5 ug of the vector (pET23(d)SK-NTR) was double-digested with 20 U of Not I and 15 U of BsmI enzymes, sequentially. The linearized vector, and insert were isolated by running a 1% agarose gel and loading the above-mentioned digestion mixtures in well-separated wells.The vector and insert bands were cut out from the agarose gel using a clean scalpel and the respective DNA fragments were purified, quantitated spectrophotometrically and ligated at a molar ratio of 1:5 of vector insert. Approximately 600 ng of the BsmI/NotI double-digested vector was ligated with around 250 ng of the BsmI/NotI double-digested insert in a 20-ul reaction by adding 600 Weiss units of ligase (NEB) and 2 ul of 10× ligase buffer (also of New England biolabs, Inc.) and incubating for 14 h at 16° C. The ligation mix was then heat-inactivated at 70° C. and 15 min, and the DNA was n-butanol precipitated, air-dried, dissolved in 20 uL of sterile water and approx. one-thirds directly used to electroporate E. coli XL-1 Blue electrocompetent cells. The transformants were selected on LB-Amp plates. Ten transformants were picked up and inoculated into fresh LB-Amp for plasmid minipreparation. The miniprep DNAs were digested with BsmI and NotI enzyme alongwith pSKMG400-FBD(1,2) as control. Three clones were positive in terms of liberating an insert equal in size to that of the insert liberated from pSKMG400-FBD(1,2). One of the clones was then sequenced to confirm the nucleotide sequence of the SK-FBD gene (see FIG. 19 b) and designated pET23(d)SK-NTR-FBD(1,2). This has been deposited with MTCC under accession No. BPL 0014. The plasmid DNA for this clone was transformed into E. coli BL-21 strain, grown in liquid culture and induced for the expression of SK-FBD(1,2) hybrid protein with IPTG, as described earlier. Cells from 1.5 ul of the induced culture were pelleted down by centrifugation and were lysed in 100 ul modified SDS-PAGE sample buffer; approx. 25 ul lysate, along with that from cells harbouring pET23(d) SK-NTR as control was analysed on 10% SDS-PAGE gel. In parallel, cultures were also grown where IPTG addition was omitted (uninduced controls) and similarly analysed alongwith induced cultures by SDS-PAGE. The gels showed distinct bands of 57 kD in the IPTG-induced cultures (roughly representing 20% of the soluble protein fraction) indicating that the hybrid SK-FBD(1,2) fusion protein had been expressed at high levels intracellularly. In the case of parallel pET23(d)SK-NTR harboring cultures, a major band corresponding to 47 kD; the position of native SK was observed.

Example 5

In-Frame Fusion of DNA Segments Encoding FBD(4,5) at the N-Terminal End of the Open-Reading-Frame Encoding for SK, and Cloning and Expression of the Hybrid Polynucleotide-Construct FBD(4,5)-SK in E. coli.

The construction of the FBD(4,5)-SK hybrid polynucleotide DNA was accomplished by the splicing overlap extension (SOE) method, a procedure in which two (or more) DNA fragments are joined together employing PCR, without using either DNA scission or ligation (in this context, reference may be made to the following publications. Horton, R.M., Hunt, H.D., Ho, S.N., Pullen, J.K., and Pease, L.R., 1989, Gene 77:61). The two fragments to be joined by SOE need to have mutually complementary sequences at their respective junctions where the joining is to take place so as to form an ‘overlap’ (see FIG. 20). These regions of complementarity can be engineered into the two DNA fragments, or ‘blocks’, to be joined (in the present case, the SK and FBD sequences) through separate PCRs each employing primers specially designed for this purpose. These two PCR-generated blocks are then used in the overlap extension reaction, in a third PCR, wherein the complementary strands hybridize partially at their 3′-ends through the regions of mutual complementarity after strand separation (denaturation) and reannealing. Thus, these two DNA strands act as megaprimers on each other, and in the presence of thermostable DNA polymerase, the 3′-ends of this intermediate are extended to form the full-length (i.e. fused) segment, which may then be further amplified using the flaking primers derived from the first two PCRs used to generate the two DNA blocks. The FBD-SK polynucleotide fusions were made using four synthetic oligonucleotide PCR primers viz., KRG-8, KRG-9, KRG-11 and KRG-12 whose sequences and design are described below (see also FIG. 19 for the overall scheme followed for the construction of the chimeric gene-construct).

Upstream PCR-I primer KRG-8:                   Transglutamate recognition site                                            150     152      154 5′-CC-ATG- GTG-CAA-GCA-CAA-CAG-ATT-GTA- CCC-ATA-GCT-GAG-AAG-TGT-3′ (SEQ ID NO:21)   Partial Nco I    site                              hybridizes it begining of FBD(4) segment                                      (codon numbers of FBD are shown as per FIG. 6) Downstream PCR-I primer KRG-9:   sequence complementary to   codons 1–5 of SK (No.'s indicated   below) 5′-C TC-AGG-TCC-AGC-AAT-ACG-AAC-ATC-GGT-GAA-GGG-GCC-AGA-T-3′ (SEQ ID NO:22)     5    4   3    2    1  259        257       255          253                          sequence hybridizing with end of FBD(5) segment (No.'s                          indicated                          are codons, as per FIG. 6). Upstream PCR-II primer, KRG-11        FBD(5) sequence, as overhang;         sequence hybridizing with SK gene; codonNo.s        Codon numbers (cf. FIG. 6)            (Cf. FIG. 3) are indicated.        are indicated.        5′- TTC-ACC-GAT-GTT-CGT-A TT-GCT-GGA-CCT-GAG-TGG-CTG-CTA-GAC-3′ (SEQ ID NO:23)          255      257 259  1  3      5        7          9 Upstream PCR-II primer, KRG-12     5′-TGG-TTT-TGA-TTT-TGG-ACT-TAA-GCC-TTG-3′        62       60  58       56      54 (SEQ ID NO:24) Note: sequence hybridizing with SK gene (codon No.'s are indicated; see FIG. 3)

As can be seen above, the upstream primer, KRG-8, was homologous to the the begining 18 nucleotides of the ‘anticoding’ strand of the FBD-4 encoding DNA and also carried at its 5′ end non-hybridizing DNA sequences that encoded for a Nco I site (to facilitate the ‘docking’ of the SOE product into the Nco I site of the expression vector, thus recreating the ORF for the FBD(4,5)-SK fusion sequences). The upstream primer also contained sequence coding for a transglutaminase cross-linking site. The downstream primer KRG-9 was designed to hybridize with the end of the FBD(5) DNA sequence, but also contained at its 5′ non-hybridising end, nucleotide complementary to the first 5 codons of the ORF encoding mature S. equisimilis SK (see FIG. 6). The template used for the first PCR to obtain Block I (see FIG. 20) was FBD(4,5) cloned in pBlueScript [pSKMG400-FBD(4,5)]. The first PCR (termed PCR-I) was carried out using approx 20 ng template and 30 pmol of each primer in a 100 uL-reaction using the buffer provided by Stratagen Inc., the supplier of the pfu thermostable polymerase. The PCR employed 25 cycles with the following conditions: 94° C. for 45 sec (denaturation step) followed by 50° C. for 1 min (annealing step), and 72 C for 1 mm (extension step). This was followed by an incubation for 4 min at 72° C. for extension of any incomplete chains. The PCR resulted in the generation of a single species of DNA, in accordance with the size expected from the fusion construct (368 bp), as observed by agarose gel electrophoresis; this DNA species was isolated from the gel as a small agarose black, and subjected to further purification using the agarase treatment method, described earlier.

For obtaining the DNA Block II for the SOE reaction, only the region of the SK-encoding polynucleotide DNA corresponding to nucleotide 1 to 186 (approx. corresponding to the first 63 amino acid residues of SK; see FIG. 3) was amplified using pSKMG400 as template in PCR II, using the primer set KRG 11 (upstream primer) and KRG 12 (downstream primer). This region encompasses the unique Afl II site in the SK gene (see FIG. 4), The upstream primer contained non-hybridizing bases that were homologous to the last five codons of the FBD(5)-encoding DNA (viz., codons 255-259), followed by a stretch of bases hybridizing to the first 27 bases of the anti-sense strand of the SK-encoding ORF (see FIG. 3). The downstream primer contained sequences hybridizing with the stretch of DNA encoding for residues 55-63 of SK containing the Afl II restriction site so that the SOE product could be docked back into the full-length SK-encoding polynucleotide segment contained in the vector used for the expression of the hybrid gene(see FIG. 21 a). The PCR was carried out essentially as described for PCR I, above, except that 90 ng of template was chosen and the cycling conditions selected had a lower annealing temp. (43° C.) dictated by a relatively lowered T_(m) of one of the primers. The PCR gave a single DNA band of the expected size (201 bp) on agarose gel electrophoresis, which was isolated and purified as for PCR I product (Block 1). Splice overlap extension reaction (PCR III) was then carried out to obtain the hybrid DNA between the FBD and SK ORFs. In this reaction, approx. equivalent amounts of the purified DNAs from PCR I and PCR II were mixed together (representing approx. one-fifteenth of the amplified DNA obtained from PCRs I and II) in a 100-uL reaction. To bring about optimal and specific annealing between the hybridizing areas of the two partially complementary strands from the FBD(4,5) and SK 1-63 DNA blocks (see. FIG. 20) (Phase 1), the reaction was first carried out in the absence of any other primers, using pfu DNA polymerase and the buffer specified by its supplier, employing the following conditions: 98° C. for 2 min, slow temperature decrease (i.e. ‘ramp’ of 4 min) to 50° C., maintainance at 50° C. for 1 min, followed by 3 min at 65° C. A ‘hot start’ was used for the initiation of the PCR (i.e. the DNA polymerase was added into the reaction after all other components had been added and thermally equilibrated to the highest temperature in the cycle). A total of 10 cycles were carried out first (Phase I), to allow formation of overlapped extended products. In the second phase, primers KRG 8 and KRG 12 were added under hot start conditions, and another 25 cycles were given at the following cycling conditions: 94° C. for 1 min (denaturation step), 40° C. for 1 min (annealing), followed by extension at 72° C. for 1 min to amplify the fusion products. Finally, after 10 min at 72° C., an aliquot from the PCR was analysed by agarose gel electrophoresis. It showed the clean appearance of the expected hybrid product (539 bp) with the absence of any other background bands. This was isolated from the agarose gel, purified and then kinased with T4 phage polynucleotide kinase by standard protocols. The kinased (i.e. 5′ -phosphorylated) product was then blunt-end cloned at the Eco RV site of pBlueScript. Clones containing the SOE product were selected by restriction enzyme digestion to isolate the inserts and measuring their size by agarose gel electrophoresis. Two positive clones were the sequenced to confirm the identity of their DNA inserts as well as the absence of any mutations(see FIG. 21 b). Nco I and Afl II digestion of one of these two clones, the Nco I-Afl II fragment carrying the FBD4(,5)-SK ‘hybrid polynucleotide cassette’ was ligated with Nco I-Afl II digested SK-expression plasmid (pET(23d )-SK) and transformation of E. coli XL-Blue cells was carried out to obtain the hybrid FBD(4,5)-SK ORF in this vector (FIG. 21 a). The resultant plasmid pET23(d)-FBD(4,5)-SK has been deposited with MTCC under accession No. BPL 0015. This plasmid construct was transformed into E. coli BL-21 cells to monitor expression of the hybrid FBD-SK construct from the T7 RNA polymerase promoter-based vector, as described before. The SDS-PAGE gels showed the expression intracellularly of a protein with the expected MW (approx. 57 kD) at a level of around 20 percent of total intracellular, soluble proteins.

Example 6

In-Frame Fusion of DNA Segments Encoding for FBD Segments 4 and 5 at both the Ends of the DNA ORF Encoding for SK, and Cloning and Expression of the Hybrid Polynucleotide-Construct So Formed, FBD(4,5)-SK-FBD(4,5), in E. coli.

The steps involved in the construction of a SK-FBD polynucleotide hybrid wherein the FBD(4,5) domains were fused in-frame simultaneously at both ends (i.e. the N- and C-termini) of the SK-encoding ORF [i.e. FBD(4,5)-SK-FBD(4,5)] are shown schematically in FIG. 22 a. It is based on the cloning of the FBD(4,5)-SK(1-57 residues) cassette obtained from pBlueScript-FBD(4,5)-SK vector, described in Example 5 (above) into pET-(23d)SK-FBD(4,5) at the begining of the ORF for SK. Approximately 5 ug each of pET(23 d)SK-FBD(4,5) and pBlueScriptFBD(4,5)-SK plasmid DNA were digested with Afl II and Nco I restriction endonucleases and the digests were electrophoresed on 1.2% agarose gels alongwith standard DNA size markers by standard methods. In each case, two fragments were observed, corresponding to the vector DNAs (expected size, 5012 bp) devoid of the Nco I-Afl II fragment, and the latter fragment [approx. 520 bp in the case of pBlueScriptFBD(4,5)-SK and 140 bp in case of pET-(23d)SK-FBD(4,5)] released from the parent vectors as a result of the double-digestion (see FIG. 22 a showing the Afl II and Nco I sites in the two vectors). The NcoI-Afl II fragment from pBlueScript FBD(4,5)-SK, containing the FBD(4,5)-SK(1-57 residues) cassette, to be used as insert, and the NcoI-AflII digested vector DNA from pET-(23d)SK-FBD(4,5) were isolated from the agarose gel and purified. Both fragments were then subjected to ligation using T4 DNA ligase under standard conditions using a molar ratio of 1:2 of vector to insert DNA. The ligation mixture was then transformed into electro-competent E. coli XL-1 Blue cells. Positive clones, with both ends of SK fused with the FBD(4,5) domains, were selected on the basis of difference in size from the parent vectors, as well as their ability to yield the expected fragment (containing FBD sequences at both ends of the insert) after digestion with Nco I and Bam HI enzymes (see FIG. 22 a). The veracity of the constructs was then established by subjecting one of the selected clones to automated DNA sequencing using Sanger's di-deoxy method to sequence the entire hybrid ORF (see FIG. 22 b). This demonstrated that the construct had the expected design and sequence, with one ‘set’ of FBD4,5 domain fused at the begining of the SK-encoding polynucleotide, and another at its end (i.e. after DNA encoding for residue 383). This plasmid construct has been designated pET23(d)FBD(4,5)-SK-FBD(45)], and deposited with MTCC (Accession No. BPL 0016 in host E. coli XL-Blue). It was also used to transform E. coli strain BL-21 electro-competent cells, in order to express the FBD-SK-FBD hybrid construct intracellularly in E. coli. The hybrid gene was then expressed in E. coli intracellularly after induction with IPTG exactly as described earlier, and the cell lysates analysed by SDS-PAGE. These showed the expression of a polypeptide of approx. MW 65 kD as expected from the incorporation of the two FBD segments at each ends of the SK (1-383) gene. The level of expression of this protein was observed to be approx. 20-25 percent of the total soluble protein fraction.

Example 7

Purification of Various Chimeric Constructs Formed Between SK and FBDs after Expression in E. coli and Refolding, and Testing of Their Affinity for Human Fibrin.

Fifty ml LB-Amp (containing 100 ug/ml of ampicillin per ml) were seeded with E. coli cells harbouring either pET23(d)-SKFBD(4,5), pET23(d)-SKFBD(1,2), pET-23(d)FBD(4,5)-SK or pET23(d)-FBD(4,5)-SK-FBD(4,5) plasmid constructs in separate flasks (150 ml capacity). The inoculation was done from the respective glycerol stocks, and the culture was incubated at 37° C. for 12 h on a rotary shaker (200 r.p.m.). This pre-inoculum was used to seed fresh LB-amp at 5% (v/v) level (one litre total for each type of E. coli BL-21 cells harbouring one of the different plasmid constructs described above with 500 ml medium per 2 liter conical flask), and the cultures shaken as above at 37° C. for approx. 2 h 30 min, at which time the OD600 of the cultures had reached a value of 1.0-1.1. The expression of chimeric SK/FBD polypeptides in the cultures were then induced by the addition of IPTG to 1 mM, and continuing further the incubation for another 3 h. Cells from all four cultures were then harvested by high-speed centrifugation (8000 g×30 min) at 4° C., and washed once with 500 ml cold ST buffer (pH 7.5). Finally, each cell pellet was suspended in cold 25 ml ST buffer, pH 8.0. The wet-weight of the pellets obtained from 1 liter cultures varied between 4.3-4.5 g. Each cell-suspension was then subjected to ultra-sonication to effect cell-lysis using standard methods. The lysates so obtained (approx. 28 ml each) were subjected to high-speed centrifugation at 4° C. to pellet any unlysed cells and/or cell debris. The protein conc. in the supernatants varied between 15.0 to 16.0 mg/ml. These were then diluted to a final protein of 1 mg/ml using distilled water, together with the addition of the following additional components (final concentrations in the diluted mix are given): Tris-Cl, pH 8.0, 50 mM; NaCl 150 mM; EDTA 1 mM; mixture of reduced and oxidized glutathione 123:50 mg. To these refolding mixtures (approx. 400 ml each) were then added 30 ml (packed volume) of fibrin-Sepharose beads pre-equilibrated with 50 mM Tris-Cl, pH 8.0. The mixtures were stirred at 22° C. for 16 h to effect reoxidation/refolding. The solutions were then passed through 50 ml-volume axial glass columns fitted with fitted glass disks (to retain the Sepharose-beads). The packed fibrin-Sepharose beds were then washed with approx. 170 ml binding buffer (50 mM tris-Cl, pH 8.0, and 150 mM NaCl), followed by 100 ml of 2 M urea (in binding buffer), and finally the fibrin-bound protein was eluted with 6 M urea (in binding buffer). All the washing/elution steps were carried out at a flow rate of −30 ml/h using a peristaltic pump assembly. The chromatographic profile in case of SK-FBD(4,5) fibrin-Sepharose affinity purification, and analysis of the different fractions, are show on FIG. 23, Similar results were obtained in case of the other SK-FBD constructs. A total of 3.8 mg of protein was eluted alongwith the 6 M urea-wash in the case of SK-FBD(4,5), whereas for SK-FBD(1,2) approx. 4 mg, for FBD(4,5)-SK 3.5 mg, and for FBD(4,5)-SK-FBD(4,5) 6.2 mg of protein was obtained at the 6 M urea elution step. In case of the SK control, no protein was found to elute alongwith the 6 M urea. The removal of the urea, and concentration of the protein, was effected by ultrafiltration through 10 kD cut-off membranes. Aliquots of each of the four fibrin-specific SK-FBD chimeric products were then subjected to SDS-PAGE analysis on 10 percent acrylamide gels with and without reduction with beta-mercaptoethanol to determine their relative purities as well as monomeric/polymeric character. Standard molecular weight marker proteins as well as pure native SK from S. equismilis were also run on the same gels. The SDS-PAGE analysis, either in the presence or absence of reducing agent, showed all of the fibrin-Sepharose eluted chimeric product to be essentially pure and monomeric; in all cases, a single prominent band stained with Coomassie Blue and very few faint background bands were visible (not more than 2-5% cumulatively). The MWs of the refolded proteins were completely in accord with those expected from theoretical considerations i.e. extrapolated from the MW of individual domains of FBD, the SK portion, and linker sequence, if present. The SK-FBD(4,5) and SK-FBD(1,2) bands moved with the same mobility on SDS-PAGE, with an apparent MW of around 55 kD; however, the FED-(4,5)-SK construct showed a slightly lowered mobility as compared to either SK-FBD(4,5) or SK-FBD(1,2). This was in accord with the fact that whereas the former two hybrid constructs contained approx. 31 amino acid residues' deletion at the C-terminal end of the SK moeity of the hybrid, the FBD(4,5)SK construct had full-length SK integrated in its design (see Examples, above). The FBD(4,5S)SK-FBD(4,5) construct, containing four FBDs alongwith SK, moved with a MW corresponding to 60 kD on SDS-PAGE. In the absence of beta-mercaptoethanol, the MW's calculated for all four hybrids were approximately the same as observed in the presence of beta-mercaptoethanol, indicating that the constructs obtained after refolding and binding with fibrin-Sepharose contained essentially monomeric forms of the polypeptides.

The specific activities of the purified proteins for PG activation, as determined by the chromogenic assay were: 2.2×10⁴ I.U./mg for SK-FBD(4,5), 1.8×10⁴ I.U./mg for SK-FBD(1,2). 4×10⁴ I.U./mg in case of FBD(4,5)-SK and 5×10² I.U./mg for FBD(4,5)-SK-FBD(4,5), respectively. Under the same conditions, native S. equisimilis SK, or SK purified from E. coli (Met-SK) as described in Example 2, above, showed a much higher activity (˜1.0×10⁵ I.U./mg). The reason for the apparently lowered specific activities in case of the chimeric proteins was revealed when these were assayed by a single-phase, continuous spectrophotometric assay by directly determining their rates (slopes) for HPG activation by standard methods (Wohl, R.C., Summaria, L., and Robbins, K.C., 1980, J. Biol. Chem. 255:2005). These assays revealed that whereas native SK or E. coli-expressed Met-SK did not display an appreciable lag in the progress curves obtained for the PG activation reactions (less than 1 min), all of the hybrid proteins displayed significant initial periods in their PG activation profiles (varying from 7 to 25 min depending on the construct) wherein little or no plasmin formation occured. However, after the initial lags, the PG activation proceeded with a high rate, generating slopes closely similar to those obtained with native SK (see below).

Example 8

Functional Characterization of the Chimeric Proteins in Terms of Their Altered Kinetics of Plasminog N Activation and Fibrin Clot Dissolution.

The proteins prepared in Example 7, above, as well as native and Met-SK (as controls) were examined with respect to their PG activation kinetics. This essentially entailed the study of the time-course of PG activation by the various SK/FBD chimeras and the determination of their steady-state kinetic constants for PG activation. A one-stage assay method was used to measure the activation of HPG; reference in this context may be made to several publications in the literature e.g.: Shi, G.Y., Chang, B.I., Chen, S.M., Wu, D.H. and Wu H.L., 1994, Biochem. J. 304:235; Wu, H.L., Shi, G.Y., and Bender, M.L., 1987, Proc. Natl. Acad. Sci. 84: 9292; Wohl, R.C., Summaria, L., and Robbing, K.C., 1980, J. Biol. Chem. 255: 2005; Nihalani, D., Raghava, G. P. S., Sahni, G., 1997, Prot. Sci. 6:1284. Briefly, it involved the addition of the activator proteins to be studied in a small aliquot (˜5 ul) into 100 ul-volume microvette containing 1 uM of HPG in assay buffer (50 mM Tris-Cl buffer, pH 7.5, containing 0.5 mM chromogenic peptide substrate and 0.1 M NaCl). The protein aliquots were added after addition of all other components into the cuvette and bringing the spectrophotometric absorbance to zero. The change in absorbance at 405 nm was then measured as a function of time in a Shimadzu UV-160 model spectrophotometer. While SK showed a rapid PG activation kinetics, the kinetics for SK-FBD chimeric protein displayed a characteristic lag, or delay, in the initial phase of the rate of PG activation that was clearly different from the rates seen with SK. This property viz., initial delay in HPG activation, as well as its magnitude, was largely independent of the amount of the chimeric protein employed in the assay, as well as the concentration of HPG in the reaction. Another notable feature was that the lag-times associated with the different chimeric proteins under the same conditions. In the case of SK-FBD(1,2) and SK-FBD(4,5) the lag period corresponded to 10-12 min, for FBD(4,5)-SK 7-8 min, and 20-25 min in case of FBD(4,5)-SK-FBD(4,5). Under the same conditions (˜uM HPG, 1-2 nM of protein), native SK or Met-SK displayed very little lag period (i.e. less than 1 min duration) during PG activation.

The mechanism of the initial lag in the various SK-FBD chimeras was investigated by examining the SDS-PAGE profiles of various aliquots withdrawn from plasminogen activation reactions withdrawn at different time-intervals after the mixing of SK or SK-FBD chimeric protein with human PG. These showed that the appearance of rapid PG activation following the lag period closely coincided with the cleavage of the FBD portion from the rest of the molecule (SK portion) as evidenced by a reduction of the molecular weight of the hybrid. That the proteolysis was mediated by trace amounts of plasmin in the system was evident by the observation that either removal of trace plasmin by passage of the human PG through soybean trypsin inhibitor agarose (a material that selectively binds plasmin and does not bind plasminogen) led to very high periods of lag for all of the hybrid proteins [viz., from 10-12 min to approx. 25 min for SK-FBD (1,2), SK-FBD(4,5, and FBD(4,5)-SK, to approx. 35 min for FBD(4,5)SK-FBD(4,5) from an initial value of approx. 20 min. Alternatively, the addition of small quantities of preformed human plasmin into the PG activation reactions (made by the conversion of PG to plasmin with agarose-immobilized urokinase) considerably reduced the lag periods associated with the different SK-FBD chimeras.

To determine the steady-state kinetic parameters for HPG activation of the activated forms of the hybrids, fixed amounts of SK or SK-FBD chimeric protein (1 nM) were added to the assay buffer containing various concentrations of HPG (ranging from 0.035 to 2.0 uM) in the 100 uL assay micro-cuvette as desribed above. The change in absorbance (representing velocity, v) was then measured spectrophotometrically at 405 nM for a period of 30 min at 22° C. All determinations were done in triplicates and their averages taken for analysis. The kinetic parameters for HPG activation were then calculated (using the linear portion of the progress curves) from inverse, Lineweaver-Burke plots using stan procedures (Wohl, R.C., Summaria, L., and Robbins, K.C., 1980., J. Biol. Chem. 255: 2,005), wherein the 1/v value is plotted on the ordinate axis and 1/S value is plotted on the abscissa, S representing the (varying) concentration of substrate (HPG) employed for the reaction/s. From these plots, the K_(m) for HPG (K_(plg)) and maximal velocities (at saturating HPG concentrations) were determined (set forth in the following Table).

These data clearly show that once fully activated after completion of the initial lag, all the chimeric constructs became significantly active in terms of their PG activator abilities in comparison to SK.

TABLE 1 Steady-state kinetic parameters for HPG activation by SK and SK-FBD hybrid proteins* ^(k)plg Maximal Lag Activator protein (uM) activity# (min) nSK 0.14 ± 0.02 100.0 1.0 Met-SK 0.18 ± 0.01 95.5 ± 5   2.0 SK-FBD(4,5) 0.15 ± 0.02 52 ± 4 10.0 SK-FBD(1,2) 0.18 ± 0.03 58 ± 5 10.5 FBD(4,5)-SK 0.16 ± 0.02 65 ± 4 8.0 FBD(4,5)-SK-FBD(4,5) 0.20 ± 0.03 45 ± 4 18.0 *The parameters were calculated from the linear phases of the reaction progress curves after the abolishment of the lag phases. ^(#)Expressed relative to the activity of native SK from Streptococcus sp. (ATCC 12449), taken as 100 percent.

In a separate series of experiments, the rates of proteolytic dissolution of radiolabelled fibrin clots in vitro was examined to test whether, like native SK, the SK-FBD chimeric proteins could also efficiently break down fibrin to soluble products, a fundamental biological property of all thrombolytic agents, and also to examine if the altered PG activation kinetics observed with synthetic peptide substrate, described above (i.e. slow initial rates, followed by rates close to those observed for native SK) were also reflected at the level of clot lysis.

Radioactive fibrin clots were first prepared by mixing 400 ul of cold fibrinogen (2.5 mg/ml stock) with 50 ul of ¹²⁵I-labelled fibrinogen containing 9×10⁵ cpm (specific activity 7.2×10⁵ cpm/ug protein) and adding to a solution (150 ul) containing 100 ug HPG and 0.25 N.I.H. units of thrombin (Sigma). All solutions were made in 0.1 M citrate phosphate buffer, pH 7.5, containing 0.8 percent BSA (BSA-cirate buffer). The final volume of the clotting reaction was adjusted to a total volume of 1 ml with BSA-citrate buffer. The clot was formed by incubating the mixture in a glass tube at 37° C. for 2 min. The clot was then washed thrice with 2 ml of TNT buffer (50 mM Tris-Cl buffer, pH 7.5, containing 38 mM NaCl and 0.01 percent Tween-80) for 3 min at 37° C. When required non-radioactive fibrin clots were prepared exactly as described above but omitting the inclusion of ¹²⁵l-labelled fibrinogen from the clotting mixture. The effect of the thrombolytic agent (native SK or SK-FBD hybrid) was then studied in terms of release of radioactivity from the clot kept either in a plasma milieau or in presence of excess human fibrinogen as described below.

Clot lysis of preformed fibrin clots suspended in human plasma was carried out by suspending ¹²⁵I-labelled and extensively washed clots in 2 ml citrated human plasma, prewarmed at 37° C., and adding different amounts of either SK or a given SK-FBD hybrid protein. The reaction tubes were rotated slowly at 37° C. in a water bath and 0.1 ml aliquots of the soluble fraction were removed at regular intervals to measure the ¹²⁵I-fibrin degradation products released by measuring the amount of radioactivity using a gamma counter. The total radioactivity in each clot was determined by measuring the radioactivity of the respective tube before withdrawing any aliquot prior to the addition of thrombolytic agent. A comparison of the dissolution kinetics of radio-labelled fibrin clots by native SK and the various SK-FBD chimeric proteins in plasma milieau also clearly showed hat the lag displayed by the latter during the PG activation assays was essentially preserved during clot lysis also. While SK caused relatively rapid dissolution of the fibrin and a patterning of the dissolution reaction at or around 15 min, a prolonged lag in the case the SK-FBD(4,5) hybrid protein (approx. 10 min) was evident at the same protein concentrating (representative data for those two proteins are shown in FIG. 24). In the case of the other hybrids; the lag-times in plasma were essentially as seen with PG activation assays viz., 10 min for SK-FBD(1,2), 8 min for FBD(4,5)-SK, and 18 min for FBD(4,5)-SK-FBD(4,5).

Clot lysis in the presence of an excess of human fibrinogen was also carried out by measuring the rate of dissolution of radio-labeled fibrin clot by SK or SK-FBD protein in the presence of various concentrations of human fibrinogen (1-4 mg/ml) and 100 nM of either SK or SK-FBD hybrid protein. Clot lysis was also performed in the presence of fixed fibrinogen concentration (2 mg/ml) but employing different concentrations of SK/SK-FBD protein (ranging from 50 to 200 nM). The reactions were incubated at 37° C. in a water bath with gentle shaking, and the release of ¹²⁵I-fibrin degradation products as a function of time was measured in the supernatant, as described above. All of the hybrid proteins were able, like SK, to dissolve the fibrin clots in a dose-dependent manner; however, there was a distinct lag in the case of the SK-FBD hybrids closely similar to that seen with clot lysis in plasma milieau. The lag period varied with construct design viz., in case of SK an absence of any appreciable lag was observed (less than 2 min). The lag times for SK-FBD(4,5) and SK-FBD(1,2) were 10-11 min; for FBD(4,5)-SK 7-8 min; and 18-20 min for FBD(4,5)-SK-FBD(4,5).

ADVANTAGES OF THE INVENTION

The advantage of the present invention lies in its disclosure of the design of structurally defined SK-FBD chimeric polynucleotide DNAs in which the translational in-frame fusion of the DNAs encoding SK, or its modified forms, and those for the minimally essential human Fibronectin gene that are capable of possessing significant fibrin affinity on their own, such as those FBDs that possess independent fibrin binding capability (e.g., “finger” domains 4 and 5 of human fibronectin) has been carried out in such a manner that the polypeptide/s expressed from these polynucleotide constructs possess fibrin affinity (which SK, on its own, does not possess) together with a delayed PG activation kinetics (unlike SK which show an immediate activation of PG).

The simultaneous presence of the afore-mentioned properties in the same PG activator confers distinct advantages into the resultant proteins. Soon after injection into the body, whilst the chimeric PG activator proteins are still in an inactive or partially active-state, they will bind to the pathological fibrin clot during their sojourn through the vascular system in an inactive/partially active state. However, after an initial lag, these will become fully activated in the immediate vicinity of the clot, thereby obviating the systemic PG activation coincident with natural SK administration. Whilst the former property would be expected to confer on the thrombolytic agent/s an ability to target itself to the immediate locale of the pathological clot and thus help build up therapeutically effective concentrations of the activator therein, the initially slowed kinetics of PG activation would result in an overall diminished generation of free plasmin in the circulation prior to their localization to the site of circulatory impedence induced by the pathological fibrin clot. The net result shall be a continued and more efficient fibrinolysis at the target sustained by considerably lowered therapeutically effective dosages of the thrombolytic agent. 

1. A nucleic acid molecule comprising a polynucleotide sequence selected from the group consisting of SEQ ID NO:9, SEQ ID NO:10, SEQ ID NO:11 and SEQ ID NO:12.
 2. The nucleic acid molecule of claim 1, wherein said polynucleotide sequence is SEQ ID NO:9.
 3. The nucleic acid molecule of claim 1, wherein said polynucleotide sequence is SEQ ID NO:10.
 4. The nucleic acid molecule of claim 1, wherein said polynucleotide sequence is SEQ ID NO:11.
 5. The nucleic acid molecule of claim 1, wherein said polynucleotide sequence is SEQ ID NO:12.
 6. A vector comprising the nucleic acid molecule of claim
 1. 7. The vector of claim 6, wherein the nucleic acid molecule is operably associated with a heterologous regulatory sequence that controls gene expression.
 8. A recombinant host cell comprising the nucleic acid molecule of claim
 1. 9. The recombinant host cell of claim 8, wherein the nucleic acid molecule is operably associated with a heterologous regulatory sequence that controls gene expression.
 10. A method for producing a polypeptide, comprising: (a) culturing the recombinant host cell of claim 9 under conditions suitable to produce the polypeptide encoded by said nucleic acid molecule, and recovering the polypeptide from the cell culture.
 11. An isolated polynucleotide comprising a nucleotide sequence selected from the group consisting of: the polynucleotide encoding the chimeric polypeptide encoded by the cDNA contained in MTCC Deposit No. 5193 (BPL 0013), the polynucleotide encoding the chimeric polypeptide encoded by the cDNA contained in MTCC Deposit No. 5194 (BPL 0014), the polynucleotide encoding the chimeric polypeptide encoded by the cDNA contained in MTCC Deposit No. 5195 (BPL 0015), and the polynucleotide encoding the chimeric polypeptide encoded by the cDNA contained in MTCC Deposit No. 5196 (BPL 0016).
 12. The nucleic acid molecule of claim 1, wherein said polynucleotide sequence is the polynucleotide encoding the chimeric polypeptide encoded by the cDNA contained in MTCC Deposit No. 5193 (BPL 0013).
 13. The nucleic acid molecule of claim 1, wherein said polynucleotide sequence is the polynucleotide encoding the chimeric polypeptide encoded by the cDNA contained in MTCC Deposit No. 5194 (BPL 0014).
 14. The nucleic acid molecule of claim 1, wherein said polynucleotide sequence is the polynucleotide encoding the chimeric polypeptide encoded by the cDNA contained in MTCC Deposit No. 5195 (BPL 0015).
 15. The nucleic acid molecule of claim 1, wherein said polynucleotide sequence is the polynucleotide encoding the chimeric polypeptide encoded by the cDNA contained in MTCC Deposit No. 5196 (BPL 0016).
 16. A vector comprising the nucleic acid molecule of claim
 11. 17. The vector of claim 16, wherein the nucleic acid molecule is operably associated with a heterologous regulatory sequence that controls gene expression.
 18. A recombinant host cell comprising the nucleic acid molecule of claim
 11. 19. The recombinant host cell of claim 18, wherein the nucleic acid molecule is operably associated with a heterologous regulatory sequence that controls gene expression.
 20. A method for producing a polypeptide, comprising: (a) culturing the recombinant host cell of claim 19 under conditions suitable to produce the polypeptide encoded by said nucleic acid molecule, and recovering the polypeptide from the cell culture. 